Magnetic crash sensor

ABSTRACT

A magnetic field is generated by at least one coil in magnetic communication with at least a portion of a vehicle responsive to a first time-varying signal operatively coupled to the at least one coil in series with a sense resistor. A second signal is generated responsive to a voltage across the sense resistor and is response to a magnetic condition of the at least one coil, which is response to the magnetic communication of the at least one coil with the portion of the vehicle.

CROSS-REFERENCE TO RELATED APPLICATIONS

The instant application is a continuation-in-part of application Ser. No. 11/932,439 (“Application '439”) filed on Oct. 31, 2007 now abandoned, which is a continuation-in-part of International Application Serial No. PCT/US06/62055 filed on Dec. 13, 2006, which is a continuation-in-part of U.S. application Ser. No. 11/530,492 (“Application '492”) filed on Sep. 11, 2006, now U.S. Pat. No. 7,514,917, which issued on 7 Apr. 2009, and which claims benefit of U.S. Provisional Application Ser. Nos. 60/750,122 filed on Dec. 13, 2005. Application '492 is a continuation-in-part of U.S. application Ser. No. 10/946,174 filed on Sep. 20, 2004, now U.S. Pat. No. 7,209,844, which issued on 24 Apr. 2007, and which claims the benefit of prior U.S. Provisional Application Ser. No. 60/504,581 filed on Sep. 19, 2003. Application '492 is also a continuation-in-part of U.S. application Ser. No. 10/905,219 filed on Dec. 21, 2004, now U.S. Pat. No. 7,212,895, which issued on 1 May 2007, and which claims the benefit of prior U.S. Provisional Application Ser. No. 60/481,821 filed on Dec. 21, 2003. Application '492 is also a continuation-in-part of U.S. application Ser. No. 11/460,982 filed on Jul. 29, 2006, now U.S. Pat. No. 7,388,370, which issued on 17 Jun. 2008, which claims the benefit of prior U.S. Provisional Application Ser. No. 60/595,718 filed on Jul. 29, 2005. Application '439 also claims the benefit of U.S. Provisional Application Ser. No. 60/892,241 filed on Feb. 28, 2007. The instant application is also a continuation-in-part of U.S. application Ser. No. 11/685,624 filed on Mar. 13, 2007 now abandoned, which is a continuation-in-part of U.S. application Ser. No. 10/666,165 filed on Sep. 19, 2003, now U.S. Pat. No. 7,190,161, which issued on 13 Mar. 2007, which is a continuation-in-part of U.S. application Ser. No. 09/649,416 filed on Aug. 26, 2000, now U.S. Pat. No. 6,777,927, which issued on 17 Aug. 2004, which claims the benefit of prior U.S. Provisional Application Ser. No. 60/151,220 filed on Aug. 26, 1999, and which claims the benefit of prior U.S. Provisional Application Ser. No. 60/151,424 filed on Aug. 26, 1999. Each of the above-identified applications is incorporated by reference in its entirety.

BRIEF DESCRIPTION OF THE DRAWINGS

In the accompanying drawings:

FIG. 1 illustrates a schematic block diagram of a magnetic crash sensor in a vehicle;

FIG. 2 illustrates a first embodiment of a first aspect of the magnetic crash sensor with the vehicle in an unperturbed state;

FIG. 3 illustrates the first embodiment of the first aspect of the magnetic crash sensor with the vehicle in a perturbed state responsive to a crash;

FIG. 4 illustrates a second aspect of a magnetic crash sensor with the vehicle in an unperturbed state;

FIG. 5 illustrates the second aspect of the magnetic crash sensor with the vehicle in a perturbed state responsive to a crash;

FIG. 6 illustrates a second embodiment of the first aspect of a magnetic crash sensor in a door of the vehicle, showing an end view cross-section of the door;

FIG. 7 illustrates the second embodiment of the first aspect of the magnetic crash sensor in the door of the vehicle, showing a top view cross-section of the door;

FIG. 8 illustrates a third embodiment of the first aspect of a magnetic crash sensor and a second embodiment of the second aspect of a magnetic crash sensor;

FIG. 9 illustrates a fourth embodiment of the first aspect of a magnetic crash sensor in the door of a vehicle, showing an end view cross-section of the door;

FIG. 10 illustrates the fourth embodiment of the first aspect of the magnetic crash sensor in the door of the vehicle, showing a top view cross-section of the door;

FIGS. 11 a and 11 b illustrate a second embodiment of a coil in accordance with the first aspect of the magnetic crash sensor;

FIG. 12 illustrates a third embodiment of a coil in accordance with the first aspect of the magnetic crash sensor;

FIG. 13 illustrates an end view of a fourth embodiment of a coil in accordance with the first aspect of the magnetic crash sensor;

FIGS. 14 a and 14 b illustrate a fifth embodiment of a coil in accordance with the first aspect of the magnetic crash sensor;

FIGS. 15 a and 15 b illustrate a sixth embodiment of a coil in accordance with the first aspect of the magnetic crash sensor;

FIG. 16 illustrates a side view of a seventh embodiment of a coil in accordance with the first aspect of the magnetic crash sensor;

FIGS. 17 a and 17 b an eighth embodiment of a coil in accordance with the first aspect of the magnetic crash sensor;

FIG. 18 illustrates a schematic block diagram of a third aspect of a magnetic crash sensing system in a vehicle;

FIG. 19 illustrates a detailed view of several coils from the third aspect illustrated in FIG. 18, and illustrates several coil embodiments;

FIG. 20 illustrates various locations for a coil around a door hinge;

FIG. 21 illustrates a coil mounted so as to provide for sensing a door opening condition;

FIG. 22 illustrates an encapsulated coil assembly;

FIG. 23 illustrates a portion of a coil assembly incorporating a magnetically permeable core;

FIG. 24 illustrates a portion of a coil assembly adapted for mounting with a fastener;

FIG. 25 illustrates a portion of a coil assembly adapted for mounting with a fastener, further comprising a magnetically permeable core;

FIGS. 26 a and 26 b illustrate eddy currents, associated magnetic fields and axial magnetic fields in various ferromagnetic elements;

FIG. 27 illustrates a toroidal helical coil;

FIG. 28 illustrates a toroidal helical coil assembly;

FIG. 29 illustrates the operation of an eddy current sensor;

FIG. 30 illustrates the operation of an eddy current sensor to detect a crack in an object;

FIG. 31 illustrates a complex impedance detected using the eddy current sensor illustrated in FIG. 30 responsive to cracks of various depths;

FIG. 32 illustrates a Maxwell-Wien bridge for measuring complex impedance;

FIG. 33 illustrates a coil of a magnetic crash sensor in proximity to a conductive element;

FIG. 34 illustrates various components of a signal from the coil illustrated in FIG. 33;

FIG. 35 illustrates a schematic block diagram of a first aspect of a signal conditioning circuit associated with a magnetic sensor;

FIG. 36 illustrates a first embodiment of a signal conditioning circuit that provides for generating one or more measures responsive to a self-impedance of a coil;

FIG. 37 illustrates a second embodiment of a signal conditioning circuit that provides for generating one or more measures responsive to a self-impedance of a coil;

FIG. 38 illustrates a third embodiment of a signal conditioning circuit that provides for generating one or more measures responsive to a self-impedance of a coil;

FIG. 39 illustrates a fourth embodiment of a signal conditioning circuit that provides for generating one or more measures responsive to a self-impedance of a coil;

FIG. 40 illustrates a fifth embodiment of a signal conditioning circuit that provides for generating one or more measures responsive to a self-impedance of a coil;

FIG. 41 illustrates a sixth embodiment of a signal conditioning circuit that provides for generating one or more measures responsive to a self-impedance of a coil;

FIG. 42 illustrates a seventh embodiment of a signal conditioning circuit that provides for generating one or more measures responsive to a self-impedance of a coil;

FIG. 43 illustrates an eighth embodiment of a signal conditioning circuit that provides for generating one or more measures responsive to a self-impedance of a coil;

FIG. 44 illustrates a ninth embodiment of a signal conditioning circuit that provides for generating one or more measures responsive to a self-impedance of a coil;

FIG. 45 illustrates a tenth embodiment of a signal conditioning circuit that provides for generating one or more measures responsive to a self-impedance of a coil;

FIG. 46 illustrates an eleventh embodiment of a signal conditioning circuit that provides for generating one or more measures responsive to a self-impedance of a coil;

FIG. 47 illustrates a block diagram of a sigma-delta converter incorporated in the eleventh embodiment of a signal conditioning circuit illustrated in FIG. 46;

FIGS. 48 a-d illustrate various outputs of the sigma-delta converter illustrated in FIG. 47 for various corresponding DC input voltages;

FIG. 49 illustrates a block diagram of a decimator comprising a low-pass sync filter a decimation filter associated with the sigma-delta converter, and a mixer, incorporated in the eleventh embodiment of a signal conditioning circuit illustrated in FIG. 46;

FIG. 50 illustrates the operation of a sigma-delta analog-to-digital converter in accordance with in the eleventh embodiment of a signal conditioning circuit illustrated in FIG. 46;

FIG. 51 illustrates embodiments of various features that can be incorporated in a signal conditioning circuit;

FIG. 52 illustrates an equivalent circuit model of a cable connected to a coil;

FIG. 53 illustrates various embodiments of various features that can be associated with an analog-to-digital converter;

FIG. 54 illustrates a twelfth embodiment of a signal conditioning circuit that provides for generating one or more measures responsive to a self-impedance of a coil;

FIG. 55 illustrates a thirteenth embodiment of a signal conditioning circuit that provides for generating one or more measures responsive to a self-impedance of a coil;

FIG. 56 illustrates a fourteenth embodiment of a signal conditioning circuit that provides for generating one or more measures responsive to a self-impedance of a coil;

FIG. 57 illustrates a gain response of a notch filter;

FIGS. 58 a-c illustrate various embodiments of notch filters;

FIG. 59 illustrates a fifteenth embodiment of a signal conditioning circuit that provides for generating one or more measures responsive to a self-impedance of a coil;

FIG. 60 illustrates gain responses a low-pass filter and a high-pass notch filter respectively overlaid upon one another;

FIG. 61 illustrates a sixteenth embodiment of a signal conditioning circuit that provides for generating one or more measures responsive to a self-impedance of a coil;

FIG. 62 illustrates a seventeenth embodiment of a signal conditioning circuit that provides for generating one or more measures responsive to a self-impedance of a coil;

FIG. 63 illustrates a eighteenth embodiment of a signal conditioning circuit that provides for generating one or more measures responsive to a self-impedance of a coil;

FIG. 64 illustrates a nineteenth embodiment of a signal conditioning circuit that provides for generating one or more measures responsive to a self-impedance of a coil;

FIG. 65 illustrates a twentieth embodiment of a signal conditioning circuit that provides for generating one or more measures responsive to a self-impedance of a coil;

FIG. 66 illustrates a twenty-first embodiment of a signal conditioning circuit that provides for generating one or more measures responsive to a self-impedance of a coil;

FIG. 67 illustrates a twenty-second embodiment of a signal conditioning circuit that provides for generating one or more measures responsive to a self-impedance of a coil;

FIG. 68 illustrates a twenty-third embodiment of a signal conditioning circuit that provides for generating one or more measures responsive to a self-impedance of a coil;

FIG. 69 a illustrates a first embodiment of a second aspect of a signal conditioning circuit that provides for generating one or more measures responsive to a self-impedance of a coil;

FIG. 69 b illustrates a model of a the coil illustrated in FIG. 69 a;

FIG. 69 c illustrates an operation of the second aspect of a signal conditioning circuit illustrated in FIG. 69 a;

FIGS. 70 a-c illustrates a various embodiments of a monopolar pulse generator in accordance with the second aspect of a signal conditioning circuit illustrated in FIG. 69 a;

FIG. 71 illustrates a second embodiment of the second aspect of a signal conditioning circuit that provides for generating one or more measures responsive to a self-impedance of a coil;

FIG. 72 illustrates a pulse train in accordance with the second embodiment of the second aspect of the signal conditioning circuit illustrated in FIG. 71;

FIG. 73 illustrates a third embodiment of the second aspect of a signal conditioning circuit that provides for generating one or more measures responsive to a self-impedance of a coil;

FIGS. 74 a-e illustrates various waveforms associated with the third embodiment of the second aspect of the signal conditioning circuit illustrated in FIG. 73;

FIG. 75 a illustrates a third aspect of a signal conditioning circuit that provides for generating one or more measures responsive to a self-impedance of a coil;

FIG. 75 b illustrates an equivalent circuit of a gyrator incorporated in the third aspect of the signal conditioning circuit illustrated in FIG. 75 a;

FIG. 76 a illustrates a fourth aspect of a signal conditioning circuit that provides for generating one or more measures responsive to a self-impedance of a coil;

FIG. 76 b illustrates a frequency dependency of the current through the coil illustrated in FIG. 76 a;

FIG. 77 illustrates a fifth aspect of a signal conditioning circuit that provides for generating one or more measures responsive to a self-impedance of a coil;

FIG. 78 illustrates a flow chart of a process for generating a half-sine waveform used in the fifth aspect of a signal conditioning circuit illustrated in FIG. 77, and a process for generating a polarity control signal used therein;

FIG. 79 illustrates a cross-section of a vehicle incorporating safety restraint actuators on opposing sides of a vehicle and associated coils of associated magnetic crash sensors associated with opposing doors of the vehicle, wherein the associated crash sensing systems cooperate with one another to mitigate the affect of electromagnetic noise;

FIG. 80 illustrates a flow chart of a process for controlling the actuation of the safety restraint actuators of the embodiment illustrated in FIG. 79, and for mitigating the affect of electromagnetic noise on the associated magnetic crash sensors;

FIG. 81 illustrates a block diagram of a magnetic crash sensing system adapted to mitigate the affect of electromagnetic noise on the associated magnetic crash sensor;

FIG. 82 illustrates a circuit for generating a signal that is a combination of a plurality of separate signals at corresponding different oscillation frequencies;

FIG. 83 illustrates a flow chart of a process for detecting signals from the magnetic crash sensing system illustrated in FIG. 81 associated with separate and different oscillation frequencies and for controlling the actuation of an associated safety restraint actuator responsive thereto while mitigating the affect of electromagnetic noise on the associated magnetic crash sensor;

FIG. 84 illustrates a flow chart of a sub-process of the process illustrated in FIG. 83, wherein the sub-process provides for determining which of the signals from the magnetic crash sensing system illustrated in FIG. 81 are representative of a crash;

FIG. 85 illustrates a flow chart of a first embodiment of a sub-process of the process illustrated in FIG. 84, wherein the first embodiment of the sub-process provides for voting and for controlling the actuation of an associated safety restraint actuator responsive thereto, so as to provide for mitigating the affect of electromagnetic noise on the associated magnetic crash sensor;

FIG. 86 illustrates a flow chart of a second embodiment of a sub-process of the process illustrated in FIG. 84, wherein the second embodiment of the sub-process provides for controlling the actuation of an associated safety restraint actuator responsive any of the signals that are indicative of a crash but which are not indicative of electromagnetic noise, so as to provide for mitigating the affect of electromagnetic noise on the associated magnetic crash sensor;

FIG. 87 illustrates a fifth embodiment of the first aspect of a magnetic crash sensor in the door of a vehicle, showing an end view cross-section of the door;

FIG. 88 illustrates the fourth embodiment of the first aspect of the magnetic crash sensor in the door of the vehicle, showing a top view cross-section of the door;

FIG. 89 illustrates a first embodiment of a coil attachment in accordance with the fourth embodiment of the first aspect of the magnetic crash sensor in the door of the vehicle;

FIG. 90 illustrates a bracket in cooperation with a door beam in accordance with the first embodiment of a coil attachment in accordance with the fourth embodiment of the first aspect of the magnetic crash sensor in the door of the vehicle;

FIG. 91 illustrates a second embodiment of a coil attachment in accordance with the fourth embodiment of the first aspect of the magnetic crash sensor in the door of the vehicle;

FIG. 92 a illustrates a first schematic block diagram of a first embodiment of a fourth aspect of a magnetic sensor in a vehicle, incorporating a plurality of non-overlapping coil elements;

FIG. 92 b illustrates a plurality of overlapping coil elements;

FIG. 92 c illustrates a plurality of coil elements, some of which are overlapping, and some of which are non-overlapping;

FIG. 93 illustrates a second schematic block diagram of the first embodiment of the fourth aspect of the magnetic sensor;

FIG. 94 illustrates a schematic block diagram of a first embodiment of the fifth aspect of a magnetic sensor;

FIG. 95 illustrates a schematic block diagram of a second embodiment of the fifth aspect of the magnetic sensor;

FIG. 96 illustrates a side view of the first embodiment of the fourth aspect of the magnetic sensor illustrating the operation thereof,

FIG. 97 illustrates a schematic block diagram of an embodiment of a sixth aspect of a magnetic sensor;

FIG. 98 illustrates a schematic block diagram of an embodiment of a seventh aspect of a magnetic sensor;

FIGS. 99 a and 99 b illustrate a first embodiment of an eighth aspect of a magnetic sensor;

FIGS. 100 a and 100 b illustrate a second embodiment of the eighth aspect of the magnetic sensor;

FIG. 101 illustrates an environment of a ninth aspect of the magnetic sensor;

FIG. 102 illustrates an embodiment of the ninth aspect of the magnetic sensor;

FIG. 103 illustrates an embodiment of a tenth aspect of a magnetic sensor associated with an air bag inflator;

FIG. 104 illustrates various embodiments of a magnetic sensor in a vehicle;

FIG. 105 illustrates a block diagram of a magnetic sensor;

FIG. 106 a illustrates a side view of a magnetic circuit;

FIG. 106 b illustrates a top view of a magnetic circuit;

FIG. 107 illustrates a block diagram of another embodiment of a magnetic sensor;

FIG. 108 illustrates a block diagram of several embodiments of a magnetic sensor incorporating first and second resonant circuits;

FIG. 109 illustrates a schematic diagram of a first coil incorporated in a magnetic sensor;

FIG. 110 illustrates a resonant behavior of a first resonant circuit;

FIG. 111 illustrates a schematic diagram of a second coil and associated capacitor incorporated in a magnetic sensor;

FIG. 112 illustrates a resonant behavior of a second resonant circuit;

FIG. 113 illustrates a process for determining a relative phase difference of two signals;

FIG. 114 illustrates a block diagram of a circuit for determining a relative phase difference of two signals;

FIG. 115 illustrates a block diagram of an embodiment of a magnetic sensor incorporating a first resonant circuit with distributed capacitance;

FIG. 116 illustrates an embodiment for detecting an opening angle of a door;

FIG. 117 illustrates an embodiment of a magnetic sensor adapted to sense both sides of a vehicle;

FIG. 118 a illustrates a plot of complex impedance of various elements of a series LC circuit;

FIG. 118 b illustrates a table of hypothetical values of resistance and inductive reactance of a series LC circuit, and the affects of changes to resistance and inductive reactance on the net impedance and phase angle of the series LC circuit;

FIG. 119 illustrates a seventh embodiment of a magnetic sensor, which incorporates a third embodiment of a series LC circuit;

FIG. 120 illustrates an eighth embodiment of a magnetic sensor, which incorporates a fourth embodiment of a series LC circuit;

FIG. 121 illustrates an embodiment of a switched capacitor circuit used in the fourth embodiment of the series LC circuit illustrated in FIG. 120; and

FIG. 122 illustrates an embodiment of a switched inductor circuit used in the fourth embodiment of the series LC circuit illustrated in FIG. 120.

DESCRIPTION OF EMBODIMENT(S)

Referring to FIGS. 1 and 2, a first embodiment of a first aspect of a magnetic crash sensor 10.1 is incorporated in a vehicle 12 and comprises at least one first coil 14 operatively associated with a first portion 16 of the vehicle 12, and a conductive element 18 either operatively associated with, or at least a part of, a proximate second portion 20 of the vehicle 12. For example, the first embodiment of the first aspect of a magnetic crash sensor 10.1 is adapted to sense a frontal crash, wherein the first portion 16 of the vehicle 12 is illustrated as comprising a front cross beam 22—the at least one first coil 14 being located proximate to a central portion thereof, e.g. mounted thereto,—and the second portion 20 of the vehicle 12 is illustrated as comprising the front bumper 24. The at least one first coil 14 is electrically conductive and is adapted for generating a first magnetic field 26 responsive to a current applied by a first coil driver 28, e.g. responsive to a first oscillatory signal generated by a first oscillator 30. The magnetic axis 32 of the at least one first coil 14 is oriented towards the second portion 20 of the vehicle 12—e.g. substantially along the longitudinal axis of the vehicle 12 for the embodiment illustrated in FIG. 1—so that the first magnetic field 26 interacts with the conductive element 18 operatively associated therewith, thereby causing eddy currents 34 to be generated therein in accordance with Lenz's Law. The conductive element 18 comprises, for example, a thin metal sheet, film or coating, comprising either a paramagnetic or diamagnetic material that is relatively highly conductive, e.g. aluminum or copper, and which, for example, could be an integral part of the second portion 20 of the vehicle 12. For example, the conductive element 18 could be spray coated onto the rear surface of the front bumper 24. The frequency of the first oscillator 30 is adapted so that the corresponding oscillating first magnetic field 26 generated by the at least one first coil 14 both provides for generating the associated eddy currents 34 in the conductive element 18, and is magnetically conducted through the ferromagnetic elements of the vehicle 12, e.g. the front cross beam 22.

The magnetic crash sensor 10.1 further comprises at least one magnetic sensor 36 that is located separate from the at least one first coil 14, and which is adapted to be responsive to the first magnetic field 26 generated by the at least one first coil 14 and to be responsive to a second magnetic field 38 generated by the eddy currents 34 in the conductive element 18 responsive to the first magnetic field 26. For example, the sensitive axis of the at least one magnetic sensor 36 is oriented in substantially the same direction as the magnetic axis 32 of the at least one first coil 14. For example, as illustrated in FIG. 1, the at least one magnetic sensor 36 comprises first 36.1 and second 36.2 magnetic sensors located proximate to the front side of respective distal portions of the front cross beam 22, so as to be responsive to first 26 and second 38 magnetic fields. The magnetic sensor 36 generates a signal responsive to a magnetic field, and can be embodied in a variety of ways, for example, including, but not limited to, a coil, a Hall-effect sensor, or a giant magnetoresistive (GMR) sensor. The first 36.1 and second 36.2 magnetic sensors are operatively coupled to respective first 40.1 and second 40.2 signal conditioner/preprocessor circuits, which, for example, provide for preamplification, filtering, synchronous demodulation, and analog to digital conversion of the associated signals from the first 36.1 and second 36.2 magnetic sensors, e.g. as described in U.S. Pat. No. 6,777,927, which is incorporated herein by reference. The first 40.1 and second 40.2 signal conditioner/preprocessor circuits are each operatively coupled to a processor 42 which processes the signals therefrom, thereby providing for discriminating a crash, and controlling an associated safety restraint actuator 44—e.g. a frontal air bag inflator or a seat belt pretensioner—operatively coupled thereto.

Referring to FIG. 3, responsive to a crash with an impacting object 46 of sufficient energy to deform the conductive element 18, changes to the shape or position of the conductive element 18 relative to the at least one first coil 14 and to the magnetic sensor 36 cause a change in the magnetic field received by the first 36.1 and second 36.2 magnetic sensors, which change is detected thereby, and a resulting signal is preprocessed by the signal conditioner/preprocessor circuits 40.1, 40.2. The signal therefrom is processed by a crash sensing algorithm in the processor 42—e.g. by comparison with a threshold or with a reference signal or waveform—and if a crash is detected thereby, e.g. a crash of sufficient severity, then the processor 42 provides for either activating the safety restraint actuator 44 responsive thereto, or provides for activation thereof responsive to a second confirmatory signal from a second crash sensor.

The first aspect of the magnetic crash sensor 10.1 provides for monitoring the shape and position of a front member of a vehicle, such as the bumper, so as to provide early warning for significant energy impacts. The magnetic crash sensor 10.1 could also provide a signal from which impacts with pedestrians can be identified and potentially differentiated from those with other low mass or unfixed objects. For example, a signal responsive to either the first 36.1 or second 36.2 magnetic sensors could be used to actuate pedestrian protection devices; to actuate resettable vehicle passenger restraint devices (e.g. mechanical seatbelt pretensioners); or to alert a frontal crash detection algorithm that a crash is beginning, wherein, for example, the frontal crash detection algorithm might adapt one or more thresholds responsive thereto. The dynamic magnitude of the signal from the magnetic sensor 36 provides a measure of crash severity.

The first aspect of the magnetic crash sensor 10.1 is useful for sensing impacts to elements of the vehicle 12 that are either non-structural or which are readily deformed responsive to a crash. Changes in elements of which the conductive element 18 is either operatively associated or at least a part of cause an associated influence of the associated magnetic field. This influence occurs at the speed of light. Furthermore, direct structural contact between the impacted element—i.e. the conductive element 18—and the associated sensing system—i.e. the at least one first coil 14 and magnetic sensor 36—is not required as would be the case for a crash sensing system dependent upon either an accelerometer or a magnetostrictive sensor, because the first aspect of the magnetic crash sensor 10.1 is responsive to changes in the geometry of the region covered by the magnetic fields associated therewith, which includes the space between the conductive element 18 and the associated at least one first coil 14 and magnetic sensor 36. The responsiveness of the first aspect of the magnetic crash sensor 10.1 is improved if these elements are located so that a nonmagnetic material gap in the associated magnetic circuit is either increased or decreased responsive to a crash, thereby affecting the overall reluctance of the associated magnetic circuit, and as a result, affecting the resulting signal sensed by the magnetic sensor 36.

The first aspect of the magnetic crash sensor 10.1 is well suited for detecting impacts to non-ferrous elements of the vehicle 12. For example, for elements that are poor conductors, the conductive element 18 operatively associated therewith provides for detecting deformations thereof. As another example, for elements that are good conductors, e.g. aluminum bumpers or body panels, those elements inherently comprise the conductive element 18 of the magnetic crash sensor 10.1.

A conductive element 18 could also be added to a ferrous element, e.g. a steel bumper, in accordance with the first aspect of the magnetic crash sensor 10.1, although in order for the effect of the second magnetic field 38 to dominate an effect of a magnetic field within the ferrous element, the associated conductive element 18 on the inside of the ferrous element (steel bumper) would need to be thick enough or conductive enough to prevent the original transmitted first magnetic field 26 from penetrating though to the steel on the other side of the conductive element 18, whereby eddy currents 34 in the conductive element 18 would substantially cancel the magnetic field at some depth of penetration into the conductive element 18 for a sufficiently thick, sufficiently conductive conductive element 18. For example, for a superconducting conductive element 18, there would be no penetration of the first magnetic field 26 into the conductive element 18. Although the depth of penetration of the first magnetic field 26 increases as the conductivity of the conductive element 18 decreases, an aluminum or copper conductive element 18 would not need to be very thick (e.g. 2 mm or less) in order to substantially achieve this effect. The depth of penetration of magnetic fields into conductive elements is known from the art using eddy currents for non-destructive testing, for example, as described in the technical paper eddyc.pdf available from the internet at http://joe.buckley.net/papers, which technical paper is incorporated herein by reference. Generally, if the thickness of the conductive element 18 exceeds about three (3) standard depths of penetration at the magnetic field frequency, then substantially no magnetic field will transmit therethrough.

Alternatively, in the case of ferromagnetic element, e.g. a steel bumper, a magnetic crash sensor could be constructed as described hereinabove, except without a separate conductive element 18, i.e. separate from the ferromagnetic element which is itself conductive. Accordingly, the first magnetic field 26 would be conducted through this ferromagnetic element second portion 20 of the vehicle 12, which is part of a magnetic circuit further comprising the at least one first coil 14, the first portion 16 of the vehicle 12, and the associated air gaps 48 between the first 16 and second 20 portions of the vehicle 12. In accordance with this aspect, the magnetic sensor 36 would be responsive to changes in the reluctance of the magnetic circuit caused by deformation or translation of the ferromagnetic first portion 16 of the vehicle 12, and by resulting changes in the associated air gaps 48.

Referring to FIGS. 1 and 4, a second aspect of a magnetic crash sensor 10.2 incorporated in a vehicle 12 comprises at least one second coil 50 operatively associated with a third portion 52 of the vehicle 12, wherein the third portion 52 can be either proximate to the above described first portion 16, or at another location. For example, the second aspect of a magnetic crash sensor 10.2 is also illustrated as being adapted to sense a frontal crash, wherein the third portion 52 of the vehicle 12 is illustrated as comprising the front cross beam 22, the second coil 50 being located proximate to a central portion thereof, e.g. located around the front cross beam 22. The second coil 50 is electrically conductive and is adapted for generating a third magnetic field 54 responsive to a current applied by a second coil driver 56, e.g. responsive to a second oscillatory signal generated by an second oscillator 58. For example, the second oscillator 58 could be either the same as or distinct from the first oscillator 30, and in the latter case, could operate at a different frequency or could generate either the same type or a different type of waveform as the first oscillator 30, e.g. square wave as opposed to sinusoidal. In one embodiment, the at least one second coil 50 is the same as the above-described at least one first coil 14. In another embodiment, the magnetic axis 60 of a separate at least one second coil 50 is oriented substantially along a ferromagnetic element of the third portion 52 of the vehicle 12, as illustrated in FIG. 1 so that the third magnetic field 54 is induced within the ferromagnetic element of the third portion 52 of the vehicle 12. In yet another embodiment, the at least one second coil 50 is placed rearward relative to the at least one first coil 14. The frequency of the second oscillator 58 is adapted so that the corresponding oscillating third magnetic field 54 generated by the at least one second coil 50 is magnetically conducted through the structural elements of the vehicle 12, e.g. the forward portion of steel frame of the vehicle 12.

The magnetic crash sensor 10.2 further comprises at least one magnetic sensor 62 that is located separate from the at least one second coil 50, and which is adapted to be responsive to the third magnetic field 54 generated by the at least one second coil 50 and conducted through the frame 64 of the vehicle 12 For example, as illustrated in FIG. 1, the at least one magnetic sensor 62 comprises third 62.1 and fourth 62.2 magnetic sensors located around the respective forward portions of the left 66.1 and right 66.2 frame rails. In another embodiment, the magnetic sensor 62 of the second aspect of the magnetic crash sensor 10.2 is the same as the magnetic sensor 36 of the first aspect of the magnetic crash sensor 10.1. The magnetic sensor 62 generates a signal responsive to a magnetic field, and can be embodied in a variety of ways, for example, including, but not limited to, a coil, a Hall-effect sensor, or a giant magnetoresistive (GMR) sensor. For example, a coil of the magnetic sensor 62 could be wound around portions of the frame 64, or the magnetic sensor 62 (i.e. coil, Hall-effect sensor, GMR sensor or other type of magnetic sensor) could be located within an opening of, or on, the frame 64 of the vehicle 12. The third 62.1 and fourth 62.2 magnetic sensors are operatively coupled to respective first 40.1 and second 40.2 signal conditioner/preprocessor circuits, which, for example, provide for preamplification, filtering, synchronous demodulation, and analog to digital conversion of the associated signals from the third 62.1 and fourth 62.2 magnetic sensors, e.g. as described in U.S. Pat. No. 6,777,927, which is incorporated herein by reference.

The third magnetic field 54 is conducted through a magnetic circuit 68 comprising the above described elements of the frame 64 of the vehicle 12, and which may further comprise elements of the body or powertrain, or other associated structural elements, particularly elements comprising ferromagnetic materials. The responsiveness of the second aspect of the magnetic crash sensor 10.2 can be enhanced if the associated magnetic circuit 68 comprises one or more gaps 70 comprising non-magnetic material, the separation thereof which is responsive to a crash to be sensed by the magnetic crash sensor 10.2, thereby modulating the associated reluctance of the magnetic circuit 68 responsive to the crash. For example, the one or more gaps 70 could comprise a structural nonferrous material, such as aluminum or structural plastic of the frame 64 of the vehicle 12, which is adapted to be either compressed or stretched responsive to the crash, causing the associated reluctance of the magnetic circuit 68 to either decrease or increase respectively.

The second aspect of the magnetic crash sensor 10.2 provides for monitoring damage to the structure of the vehicle 12 responsive to crashes involving a substantial amount of associated inelastic deformation. Referring to FIG. 5, responsive to a crash with an impacting object 46 of sufficient energy to deform the frame 64 of the vehicle 12, associated changes in the reluctance of the associated magnetic circuit 68 responsive to an associated change in the geometry of the associated elements cause an associated change in the magnetic field sensed by the third 62.1 and fourth 62.2 magnetic sensors, which change is detected thereby, and a resulting signal is preprocessed by the signal conditioner/preprocessor circuits 40.1, 40.2. The signal therefrom is processed by a crash sensing algorithm in the processor 42—e.g. by comparison with a threshold or with a reference signal or waveform—and if a crash is detected thereby, e.g. a crash of sufficient severity, then the processor 42 provides for either activating the safety restraint actuator 44 responsive thereto. The detection process of the second aspect of the magnetic crash sensor 10.2 can be made responsive to a detection of a crash in accordance with the first aspect of the magnetic crash sensor 10.1.

Generally, during major crash events where deployment of the safety restraint actuator 44 is desired, significant associated damage and associated metal bending generally occurs to vehicle structures rearward of the front bumper region. After the impacting object 46 has been detected by the first embodiment of the first aspect of the magnetic crash sensor 10.1 as described hereinabove, the vehicle crush zone and crush pattern will generally either be limited to primarily the bumper region or will extend further into the vehicle, impacting one or more major vehicle structural members. If the object intrusion is limited primarily to the bumper or hood region, then a crash would likely be detected only by the first aspect of the magnetic crash sensor 10.1. However, if the impacting object 46 intrudes on a major structural member, then a significant signal change is detected by the third 62.1 and fourth 62.2 magnetic sensors of the second embodiment of the magnetic crash sensor 10.2 responsive to a deformation of the frame 64 of the vehicle 12. The signature of the signal(s) from either of the third 62.1 and fourth 62.2 magnetic sensors, i.e. the associated magnitude and rate of change thereof, can be correlated with impact severity and can be used to actuate one or more safety restraint actuators 44 appropriate for the particular crash. Accordingly, in combination, the first 10.1 and second 10.2 aspects of the magnetic crash sensor provide for faster and better crash discrimination, so as to provide for either actuating or suppressing actuation of the associated safety restraint actuators 44. Furthermore, the affects of a crash on the magnetic circuits of either the first 10.1 or second 10.2 aspects of the magnetic crash sensor are propagated to the respective magnetic sensors 26, 62 at the speed of light, and accordingly is not limited by the speed with which shock waves propagate through the associated structural elements, as would be the case for either accelerometer or magnetostrictive sensing technologies. Furthermore, in combination, the first 10.1 and second 10.2 aspects of the magnetic crash sensor provide for detecting and differentiating various types of frontal impacts, including but not limited to, impacts with pedestrians, other vehicles, fixed objects or other objects, so as to further provide for deploying safety measures that are appropriate to the particular situation, and responsive to the predicted type of impacting object and the detected severity of the impact. Furthermore, the first 10.1 and second 10.2 aspects of the magnetic crash sensor, provide for relatively fast detection of collisions, differentiation between events requiring the actuation of a safety restraint actuator 44 from those for which the actuation thereof should be suppressed, and determination of the location, extent and energy of the collision from the information of the collision that can be detected using the signals from the associated magnetic sensors 26, 62 responsive to the associated magnetic fields 26, 38, 54 of the magnetic crash sensors 10.1, 10.2.

Referring to FIGS. 6 and 7, in accordance with a second embodiment of the first aspect of a magnetic crash sensor 10.1′ adapted to sense a side impact crash, at least one coil 14, 72 and an associated at least one magnetic sensor 74 are operatively associated with a first portion 76 of a door 78 of a vehicle 12, and are adapted to cooperate with at least one conductive element 80 that is operatively associated with, or at least a part of, a proximate second portion 82 of the door 78. For example, in the embodiment illustrated in FIGS. 6 and 7, the first portion 76 of the door 78 comprises an inner panel 84, and the at least one conductive element 80 comprises first 86 and second 88 conductive elements at the outer skin 90 and the door beam 92 of the door 78 respectively, the outer skin 90 and the door beam 92 constituting respective second portions 82 of the door 78. Alternatively, either the outer skin 90 or the door beam 92, if conductive, could serve as the associated conductive element 80 without requiring separate first 86 or second 88 conductive elements that are distinct from the outer skin 90 or the door beam 92 respectively.

The at least one coil 14, 72 is electrically conductive and is adapted for generating a first magnetic field 94 responsive to a current applied by a coil driver 96, e.g. responsive to a first oscillatory signal generated by an oscillator 98. The magnetic axis 100 of the at least one coil 14, 72 is oriented towards the second portion 82 of the door 78—e.g. towards the outer skin 90 of the door 78, e.g. substantially along the lateral axis of the vehicle for the embodiment illustrated in FIGS. 6 and 7—so that the first magnetic field 94 interacts with the conductive elements 86, 88 operatively associated therewith, thereby causing eddy currents 102 to be generated therein in accordance Lenz's Law. The conductive elements 86, 88 each comprise, for example, a thin metal sheet, film or coating, comprising either a paramagnetic or diamagnetic material that is relatively highly conductive, e.g. aluminum or copper, and which, for example, could be an integral part of the second portion 82 of the door 78. For example, the conductive elements 86, 88 could be in the form of relatively thin plates, a film, or a coating that is mounted on, applied to, or integrated with existing or supplemental structures associated with the door beam 92 and the inside surface of the outer skin 90 of the door 78 respectively. The frequency of the oscillator 98 is adapted so that the corresponding oscillating magnetic field generated by the at least one coil 14, 72 both provides for generating the associated eddy currents 102 in the conductive elements 86, 88, and is magnetically conducted through the ferromagnetic elements of the door 78 and proximate structure of the vehicle 12.

The at least one magnetic sensor 74 is located separate from the at least one coil 14, 72, and is adapted to be responsive to the first magnetic field 94 generated by the at least one coil 14, 72 and to be responsive to a second magnetic field 104 generated by the eddy currents 102 in the conductive elements 86, 88 responsive to the first magnetic field 94. For example, the sensitive axis of the at least one magnetic sensor 74 is oriented in substantially the same direction as the magnetic axis 100 of the at least one coil 14, 72. The magnetic sensor 74 generates a signal responsive to a magnetic field, and can be embodied in a variety of ways, for example, including, but not limited to, a coil, a Hall-effect sensor, or a giant magnetoresistive (GMR) sensor. The number of magnetic sensors 74 and the spacing and positioning thereof on the inner panel 84 of the door 78 is dependent upon the vehicle 12, the type of performance required, and associated cost constraints. Generally, more magnetic sensors 74 would possibly provide higher resolution and faster detection speed, but at increased system cost. Increasing either the vertical or fore/aft spacing between two or more magnetic sensors 74 reduces associated coupling with the first magnetic field 94, increases coupling with the second magnetic field 104, and provides for a more general or average indication of electrically conductive element movement during a crash, potentially slowing the ultimate detection response, but increasing immunity to false positive crash detections, i.e. immunity to non-crash events. With only one coil 14, 72 and one magnetic sensor 74, it may be beneficial to provide a separation thereof of about ¼ to ⅓ the length of a major diagonal though the cavity within the door 78.

The at least one magnetic sensor 74 is operatively coupled to a respective signal conditioner/preprocessor circuit 106, which, for example, provide for preamplification, filtering, synchronous demodulation, and analog to digital conversion of the associated signals from the at least one magnetic sensor 74, e.g. as described in U.S. Pat. No. 6,777,927, which is incorporated herein by reference. The signal conditioner/preprocessor circuit 106 is operatively coupled to a processor 108 which processes the signal therefrom, thereby providing for discriminating a crash, and controlling an associated safety restraint actuator 110—e.g. a side air bag inflator—operatively coupled thereto.

In operation, the magnetic crash sensor 10.1′ provides a measure of the relative motion of either the outer skin 90 or the door beam 92 relative to the inner panel 84 of the door 78, for example, as caused by a crushing or bending of the door 78 responsive to a side-impact of the vehicle 12. During non-crash conditions, an oscillating magnetic field resulting from the combination of the first 94 and second 104 magnetic fields would be sensed by the at least one magnetic sensor 74. If an object impacted the outer skin 90 of the door 78 causing a physical deflection thereof, then this oscillating magnetic field would be perturbed at least in part by changes in the second magnetic field 104 caused by movement or deformation of the associated first conductive element 86 and the associated changes in the associated eddy currents 102 therein. If the impact is of sufficient severity, then the door beam 92 and the associated second conductive element 88 would also be moved or deformed thereby, causing additional and more substantial changes in the associated eddy currents 102 in the second conductive element 88 and the corresponding second magnetic field 104. Generally, the door beam 92 and associated second conductive element 88 would either not be significantly perturbed or would only be perturbed at a reduced rate of speed during impacts that are not of sufficient severity to warrant deployment of the associated safety restraint actuator 110, notwithstanding that there may be substantial associated deformation of the outer skin 90 of the door 78. Accordingly, in a magnetic crash sensor 10.1′ incorporating only a single conductive element 80, a preferred location thereof would be that of the second conductive element 88 described hereinabove.

In accordance with another embodiment, an accelerometer 112, or another crash sensor, could be used in combination with the above-described magnetic crash sensor 10.1′ in order to improve reliability by providing a separate confirmation of the occurrence of an associated crash, which may be useful in crashes for which there is not a significant deflection of either the outer skin 90 of the door 78, or of the door beam 92, relatively early in the crash event—for example, as a result of a pole impact centered on the B-pillar or a broad barrier type impact that spans across and beyond the door 78—for which the magnetic crash sensor 10.1′, if used alone, might otherwise experience a delay in detecting the crash event. For example, a supplemental accelerometer 112 might be located at the base of the B-pillar of the vehicle 12. As another example, an additional supplemental accelerometer 112 might be located proximate to the safety restraint actuator 110. In a system for which the magnetic crash sensor 10.1′ is supplemented with a separate crash sensor, e.g. an accelerometer 112, the safety restraint actuator 110 would be deployed either if the magnetic crash sensor 10.1′ detected a significant and relatively rapid change in the magnetic field in combination with the acceleration exceeding a relatively low threshold, or if the accelerometer 112 detected a significant and relatively rapid change in acceleration in combination with the magnetic crash sensor 10.1′ detecting at least a relatively less significant and relatively less rapid change in the magnetic field.

It should be understood, that the performance of a coil used for either generating or sensing a magnetic field may sometimes be enhanced by the incorporation of an associated magnetic core of relatively high magnetic permeability. Furthermore, it should be understood that the signal applied to either the at least one first coil 14, second coil 50 or of coil 14, 72 could be a direct current signal so as to create a steady magnetic field. Alternatively, those coils could be replaced with corresponding permanent magnets, whereby the associated magnetic crash sensors 10.1, 10.1′ or 10.2 would then be responsive to transients in the magnetic fields responsive to an associated crash. Furthermore, it should be understood that the particular oscillatory waveform of the first oscillator 30, second oscillator 58 or oscillator 98 is not limiting, and could be, for example, a sine wave, a square wave, a sawtooth wave, or some other waveform; of a single frequency, or of plural frequencies that are either stepped or continuously varied.

Referring to FIG. 8, a third embodiment of a first aspect of a magnetic crash sensor 10.1″ is incorporated in a vehicle 12 and comprises at least one first coil 14 operatively associated with a first portion 16 of the vehicle 12, and a conductive element 18 either operatively associated with, or at least a part of, a proximate second portion 20 of the vehicle 12. For example, the third embodiment of a first aspect of a magnetic crash sensor 10.1″ is adapted to sense a frontal crash, wherein the first portion 16 of the vehicle 12 is illustrated as comprising a front cross beam 22—the at least one first coil 14 being located proximate to a central portion thereof, e.g. mounted thereto,—and the second portion 20 of the vehicle 12 is illustrated as comprising the front bumper 24. The at least one first coil 14 is electrically conductive and is adapted for generating a first magnetic field 26 responsive to a current applied by a first coil driver 28, e.g. responsive to a first oscillatory signal generated by a first oscillator 30. The magnetic axis 32 of the at least one first coil 14 is oriented towards the second portion 20 of the vehicle 12—e.g. substantially along the longitudinal axis of the vehicle 12 for the embodiment illustrated in FIG. 8—so that the first magnetic field 26 interacts with the conductive element 18 operatively associated therewith, thereby causing eddy currents 34 to be generated therein in accordance with Lenz's Law. The conductive element 18 comprises, for example, a thin metal sheet, film or coating, comprising either a paramagnetic or diamagnetic material that is relatively highly conductive, e.g. aluminum or copper, and which, for example, could be an integral part of the second portion 20 of the vehicle 12. For example, the conductive element 18 could be spray coated onto the rear surface of the front bumper 24. The frequency of the first oscillator 30 is adapted so that the corresponding oscillating first magnetic field 26 generated by the at least one first coil 14 provides for generating the associated eddy currents 34 in the conductive element 18.

The at least one first coil 14 is operatively coupled to a signal conditioner/preprocessor circuit 114.1 which, for example, provides for preamplification, filtering, synchronous demodulation and analog to digital conversion of the associated signal from the at least one first coil 14. The signal conditioner/preprocessor circuit 114.1 is operatively coupled to a processor 116 which processes the signals therefrom, thereby providing for discriminating a crash, and controlling an associated safety restraint actuator 44—e.g. a frontal air bag inflator or a seat belt pretensioner—operatively coupled thereto. More particularly, the processor 116 provides for determining a measure responsive to the self-impedance of the at least one first coil 14 responsive to an analysis of the complex magnitude of the signal from the at least one first coil 14, for example, in relation to the signal applied thereto by the associated oscillator 30.

Responsive to a crash with an impacting object 46 (e.g. as illustrated in FIG. 3) of sufficient energy to deform the conductive element 18, changes to the shape or position of the conductive element 18 relative to the at least one first coil 14 affects the magnetic field affecting the at least one first coil 14. A resulting signal is preprocessed by the signal conditioner/preprocessor circuit 114.1, which provides for measuring the signal across the at least one first coil 14 and provides for measuring the signal applied thereto by the associated coil driver 28. The signal conditioner/preprocessor circuit 114.1—alone, or in combination with the processor 116, provides for decomposing the signal from the at least one first coil 14 into real and imaginary components, for example, using the signal applied by the associated coil driver 28 as a phase reference.

The decomposition of a signal into corresponding real and imaginary components is well known in the art, and may be accomplished using analog circuitry, digital circuitry or by software or a combination thereof. For example, U.S. Pat. Nos. 4,630,229, 6,005,392 and 6,288,536—all of which is incorporated by reference herein in their entirety—each disclose various systems and methods for calculating in real-time the real and imaginary components of a signal which can be used for processing the signal from the at least one first coil 14. A Maxwell-Wien bridge, e.g. incorporated in the signal conditioner/preprocessor circuit 114.1, may also be used to determine the real and imaginary components of a signal, or a phase-locked loop may be used to determine the relative phase of a signal with respect to a corresponding signal source, which then provides for determining the associated real and imaginary components. Various techniques known from the field eddy current inspection can also be used for processing the signal from the at least one first coil 14, for example, as disclosed in the Internet web pages at http://www.ndt-ed.org/EducationResources/CommunityCollege/EddyCurrents/cc_ec_index.htm, which are incorporated herein by reference. The magnetic sensor 10 can employ various signal processing methods to improve performance, for example, multiple frequency, frequency hopping, spread spectrum, amplitude demodulation, phase demodulation, frequency demodulation, etc.

A signal responsive to the self-impedance of the at least one first coil 14—e.g. responsive to the real and imaginary components of the signal from the one first coil 14—is processed by a crash sensing algorithm in the processor 116—e.g. by comparison with a threshold or with a reference signal or waveform—and if a crash is detected thereby, e.g. a crash of sufficient severity, then the processor 42 provides for either activating the safety restraint actuator 44 responsive thereto, or provides for activation thereof responsive to a second confirmatory signal from a second crash sensor.

Referring to FIG. 8, and further to the teachings of U.S. Pat. No. 6,587,048, which is incorporated herein by reference, a second embodiment of a second aspect of a magnetic crash sensor 10.2′ incorporated in a vehicle 12 comprises at least one second coil 50 operatively associated with a third portion 52 of the vehicle 12, wherein the third portion 52 can be either proximate to the above described first portion 16, or at another location. For example, the second aspect of a magnetic crash sensor 10.2 is also illustrated as being adapted to sense a frontal crash, wherein the third portion 52 of the vehicle 12 is illustrated as comprising the front cross beam 22, the second coil 50 being located proximate to a central portion thereof, e.g. located around the front cross beam 22. The second coil 50 is electrically conductive and is adapted for generating a third magnetic field 54 responsive to a current applied by a second coil driver 56, e.g. responsive to a second oscillatory signal generated by an second oscillator 58. For example, the second oscillator 58 could be either the same as or distinct from the first oscillator 30, and in the latter case, could operate at a different frequency or could generate either the same type or a different type of waveform as the first oscillator 30, e.g. square wave as opposed to sinusoidal. In one embodiment, the at least one second coil 50 is the same as the above-described at least one first coil 14. In another embodiment, the magnetic axis 60 of a separate at least one second coil 50 is oriented substantially along a ferromagnetic element of the third portion 52 of the vehicle 12, as illustrated in FIG. 8 so that the third magnetic field 54 is induced within the ferromagnetic element of the third portion 52 of the vehicle 12. In yet another embodiment, the at least one second coil 50 is placed rearward relative to the at least one first coil 14. The frequency of the second oscillator 58 is adapted so that the corresponding oscillating third magnetic field 54 generated by the at least one second coil 50 is magnetically conducted through the structural elements of the vehicle 12, e.g. the forward portion of steel frame of the vehicle 12.

The at least one second coil 50 is operatively coupled to a signal conditioner/preprocessor circuit 114.2 which, for example, provides for preamplification, filtering, synchronous demodulation and analog to digital conversion of the associated signal from the at least one second coil 50. The signal conditioner/preprocessor circuit 114.2 is operatively coupled to a processor 116 which processes the signals therefrom, thereby providing for discriminating a crash, and controlling an associated safety restraint actuator 44—e.g. a frontal air bag inflator or a seat belt pretensioner—operatively coupled thereto. More particularly, the processor 116 provides for determining a measure responsive to the self-impedance of the at least one second coil 50 responsive to an analysis of the complex magnitude of the signal from the at least one second coil 50, for example, in relation to the signal applied thereto by the associated oscillator 58.

The third magnetic field 54 is conducted through a magnetic circuit 68 comprising the above described elements of the frame 64 of the vehicle 12, and which may further comprise elements of the body or powertrain, or other associated structural elements, particularly elements comprising ferromagnetic materials. The responsiveness of the second aspect of the magnetic crash sensor 10.2′ can be enhanced if the associated magnetic circuit 68 comprises one or more gaps 70 comprising non-magnetic material, the separation thereof which is responsive to a crash to be sensed by the magnetic crash sensor 10.2′, thereby modulating the associated reluctance of the magnetic circuit 68 responsive to the crash. For example, the one or more gaps 70 could comprise a structural nonferrous material, such as aluminum or structural plastic of the frame 64 of the vehicle 12, which is adapted to be either compressed or stretched responsive to the crash, causing the associated reluctance of the magnetic circuit 68 to either decrease or increase respectively.

The signal conditioner/preprocessor circuit 114.2 provides for measuring the signal across the at least one second coil 50 and provides for measuring the signal applied thereto by the associated coil driver 56. The signal conditioner/preprocessor circuit 114.2—alone, or in combination with the processor 116, provides for decomposing the signal from the at least one second coil 50 into real and imaginary components, for example, using the signal applied by the associated oscillator 58 as a phase reference. A signal responsive to the self-impedance of the at least one second coil 50—e.g. responsive to the real and imaginary components of the signal from the one second coil 50—is processed by a crash sensing algorithm in the processor 116—e.g. by comparison with a threshold or with a reference signal or waveform—and if a crash is detected thereby, e.g. a crash of sufficient severity, then the processor 42 provides for either activating the safety restraint actuator 44 responsive thereto, or provides for activation thereof responsive to a second confirmatory signal from a second crash sensor.

It should be understood that the third embodiment of a first aspect of a magnetic crash sensor 10.1″ and the second embodiment of a second aspect of a magnetic crash sensor 10.2′ may be used either in combination—as illustrated in FIG. 8, or either of the embodiments may be used alone.

Referring to FIGS. 9 and 10, in accordance with a fourth embodiment of the first aspect of a magnetic crash sensor 10.1′″ adapted to sense a side impact crash, at least one coil 14, 72 is operatively associated with a first portion 76 of a door 78 of a vehicle 12, and is adapted to cooperate with at least one conductive element 80 that is operatively associated with, or at least a part of, a proximate second portion 82 of the door 78. For example, in the embodiment illustrated in FIGS. 9 and 10, the first portion 76 of the door 78 comprises the inner panel 84, and the at least one conductive element 80 comprises first 86 and second 88 conductive elements at the outer skin 90 and the door beam 92 of the door 78 respectively, the outer skin 90 and the door beam 92 constituting respective second portions 82 of the door 78. Alternatively, either the outer skin 90 or the door beam 92, if conductive, could serve as the associated conductive element 80 without requiring separate first 86 or second 88 conductive elements that are distinct from the outer skin 90 or the door beam 92 respectively.

The at least one coil 14, 72 is electrically conductive and is adapted for generating a first magnetic field 94 responsive to a current applied by a coil driver 96, e.g. responsive to a first oscillatory signal generated by an oscillator 98. The magnetic axis 100 of the at least one coil 14, 72 is oriented towards the second portion 82 of the door 78—e.g. towards the outer skin 90 of the door 78, e.g. substantially along the lateral axis of the vehicle for the embodiment illustrated in FIGS. 9 and 10—so that the first magnetic field 94 interacts with the conductive elements 86, 88 operatively associated therewith, thereby causing eddy currents 102 to be generated therein in accordance Lenz's Law. For example, the at least one coil 14, 72 may comprise a coil of wire of one or more turns, or at least a substantial portion of a turn, wherein the shape of the coil 14, 72 is not limiting, and may for example be circular, elliptical, rectangular, polygonal, or any production intent shape. For example, the coil 14, 72 may be wound on a bobbin, and, for example, sealed or encapsulated, for example, with a plastic or elastomeric compound adapted to provide for environmental protection and structural integrity. The resulting coil assembly may further include a connector integrally assembled, e.g. molded, therewith. Alternatively, the at least one coil 14, 72 may be formed by wire bonding, wherein the associated plastic coating is applied during the associated coil winding process.

In one embodiment, the size and shape of the coil 14, 72 are adapted so that the induced first magnetic field 94 covers the widest portion of the door 78. In another embodiment, depending on door 78 structural response, this coverage area can be reduced or shaped to best respond to an intruding metal responsive to a crash. For example, a CAE (Computer Aided Engineering) analysis involving both crash structural dynamics and/or electromagnetic CAE can be utilized to determine or optimized the size, shape, thickness—i.e. geometry—of the coil 14, 72 that both satisfies associated packaging requirements within the door 78 and provides sufficient crash detection capability.

For example, in one embodiment, an assembly comprising the at least one coil 14, 72 is positioned within the door 78 of the vehicle 12 so that the magnetic axis 100 of the at least one coil 14, 72 is substantially perpendicular to the outer skin 90 of the door 78, wherein the outer skin 90 is used as an associated sensing surface. Alternatively, the mounting angle relative to the outer skin 90 may be optimized to account for the shape of the associated metal surface and the relative proximity an influence of an associated door beam 92 or other structural elements relative to the outer skin 90. The position of the coil 14, 72 may be chosen so that the coil 14, 72 is responsive to structures, structural elements or body elements that typically intrude relative to an occupant responsive to a crash, so as to provide for optimizing responsiveness to a measure of crash intrusion for ON crashes, while also providing for sufficient immunity to OFF crashes, for both regulatory and real world crash modes. For example, the coil 14, 72 within the door 78 could be adapted to be responsive to the outer skin 90, a conductive element 80, 86 operatively associated therewith, a door beam 92, a conductive element 80, 88 operatively associated therewith, or an edge wall 118 of the door 78, either individually or in combination.

The position, size, thickness of the chosen sensor coil 14, 72 are selected to fit within the mechanical constraints of and within the door 78 associated with electrical or mechanical functions such as window movement, door 78 locks, etc. For example, in accordance with one embodiment, the coil 14, 72 is affixed to an inner portion of the door 78, for example, through rigid and reliable attachment to an inner panel 84 of the door 78 b, so as to reduce or minimize vibration of the coil 14, 72 relative to the associated conductive element 80 being sensed (e.g. a metallic outer skin 90 of the door 78). For example, in accordance with another embodiment, the sensing coil 14, 72 could molded into an inner panel 84 of the door 78 during the manufacturing of the door 78, and/or the inner panel 84 could be adapted to provide for a snap insert for the sensing coil 14, 72 therein.

For a coil 14, 72 mounted within the door 78, the coil 14, 72 position/location may be chosen such that any conductive and/or ferromagnetic structural or body elements proximate to the inside side of the coil 14, 72 are relatively rigidly fixed so as reduce electromagnetic influences of these elements on the coil 14, 72, thereby emphasizing an influence of a crash intrusion from the exterior side of the door 78. Accordingly, it is beneficial for the coil 14, 72 to be relatively rigidly mounted to within the vehicle 12 so that the amount of relative motion between the coil 14, 72 and any nearby conductive materials is limited when actual metal deformation/intrusion does not occur, for example, as a result of vibration, particularly for conductive materials within about one coil radius of the coil 14, 72.

The coil 14, 72 would be mounted so as to be responsive to the surface being sensed or monitored. For example, in one embodiment, the coil 14, 72 is mounted a distance within about one coil 14, 72 radius (e.g. for a circular coil 14, 72) away from the outer skin 90 or target conductive element 80, 86, 88 to be monitored. The coil 14, 72 does not require any particular shape, and regardless of the shape, the associated effective sensing distance can be measured experimentally. The particular distance of the coil 14, 72 from the element or surface being sensed will depend upon the particular application. Generally, a range of mounting distances is possible. For example, the coil 14, 72 could be placed relatively close to the element or surface being sensed provide that the coil 14, 72 is not damaged during OFF conditions. Alternatively, the coil 14, 72 could be placed more than one radius away from the element or surface being sensed in order to reduce mechanical abuse susceptibility, provided that the structure of the door 78 provided for relatively greater movement of the outer skin 90 during non-crash, abuse events. Testing has shown that using a bridge circuit in the signal conditioner/preprocessor circuit 114 to improve sensitivity, changes to signal from coil 14, 72 responsive to the element or surface being sensed can be detected even when the distance from the coil 14, 72 to the element or surface being sensed is greater than one radius, however electromagnetic interference may limit the extent to which this extended range may be utilized in some situations.

Generally the coil 14, 72 comprises an element or device that operates in accordance with Maxwell's and Faraday's Laws to generate a first magnetic field 94 responsive to the curl of an associated electric current therein, and similarly to respond to a time-varying first magnetic field 94 coupled therewith so as to generate a voltage or back-EMF thereacross responsive thereto, responsive to the reluctance of the magnetic circuit associated therewith.

The conductive elements 86, 88 each comprise, for example, a thin metal sheet, film or coating, comprising either a paramagnetic or diamagnetic material that is relatively highly conductive, e.g. aluminum or copper, and which, for example, could be an integral part of the second portion 82 of the door 78. For example, the conductive elements 86, 88 could be in the form of relatively thin plates, a film, a tape (e.g. aluminum or copper), or a coating that is mounted on, applied to, or integrated with existing or supplemental structures associated with the door beam 92 and the inside surface of the outer skin 90 of the door 78 respectively.

The frequency of the oscillator 98 is adapted so that the corresponding oscillating magnetic field generated by the at least one coil 14, 72 both provides for generating the associated eddy currents 102 in the conductive elements 86, 88, and is magnetically conducted through the ferromagnetic elements of the door 78 and proximate structure of the vehicle 12.

The at least one coil 14, 72 is responsive to both the first magnetic field 94 generated by the at least one coil 14, 72 and a second magnetic field 104 generated by the eddy currents 102 in the conductive elements 86, 88 responsive to the first magnetic field 94. The self-impedance of the coil 14, 72 is responsive to the characteristics of the associated magnetic circuit, e.g. the reluctance thereof and the affects of eddy currents in associated proximal conductive elements. Accordingly, the coil 14, 72 acts as a combination of a passive inductive element, a transmitter and a receiver. The passive inductive element exhibits self-inductance and self resistance, wherein the self-inductance is responsive to the geometry (coil shape, number of conductors, conductor size and cross-sectional shape, and number of turns) of the coil 14, 72 and the permeability of the associated magnetic circuit to which the associated magnetic flux is coupled; and the self-resistance of the coil is responsive to the resistivity, length and cross-sectional area of the conductors constituting the coil 14, 72. Acting as a transmitter, the coil 14, 72 generates and transmits a first magnetic field 94 to its surroundings, and acting as a receiver, the coil 14, 72 generates a voltage responsive to a time varying second magnetic field 104 generated by eddy currents in associated conductive elements within the surroundings, wherein the eddy currents are generated responsive to the time varying first magnetic field 94 generated and transmitted by the coil 14, 72 acting as a transmitter. The signal generated by the coil 14, 72 responsive to the second magnetic field 104 received by the coil 14, 72, in combination with the inherent self-impedance of the coil 14, 72, causes a complex current within or voltage across the coil 14, 72 responsive to an applied time varying voltage across or current through the coil 14, 72, and the ratio of the voltage across to the current through the coil 14, 72 provides an effective self-impedance of the coil 14, 72, changes of which are responsive to changes in the associated magnetic circuit, for example, resulting from the intrusion or deformation of proximal magnetic-field-influencing—e.g. metal—elements.

The at least one coil 14, 72 is operatively coupled to a signal conditioner/preprocessor circuit 114, which, for example, provides for preamplification, filtering, synchronous demodulation, and analog to digital conversion of the associated signal(s) therefrom, e.g. as described in U.S. Pat. Nos. 6,587,048 and 6,777,927, which is incorporated herein by reference. The signal conditioner/preprocessor circuit 114 is operatively coupled to a processor 116 which processes the signal therefrom, thereby providing for discriminating a crash, and controlling an associated safety restraint actuator 110—e.g. a side air bag inflator—operatively coupled thereto. More particularly, the signal conditioner/preprocessor circuit 114 provides for determining a measure responsive to the self-impedance of the at least one coil 14, 72 responsive to an analysis of the complex magnitude of the signal from the at least one coil 14, 72, for example, in relation to the signal applied thereto by the associated oscillator 98. For example, in one embodiment, the signal conditioner/preprocessor circuit 114, coil driver 96, oscillator 98 and processor 108 are incorporated in an electronic control unit 120 that is connected to the at least one coil 14, 72 with standard safety product cabling 122, which may include associated connectors.

In operation, the magnetic crash sensor 10.1′″ provides a measure of the relative motion of either the outer skin 90 or the door beam 92 relative to the inner panel 84 of the door 78, for example, as caused by a crushing or bending of the door 78 responsive to a side-impact of the vehicle 12. During non-crash conditions, an oscillating magnetic field resulting from the combination of the first 94 and second 104 magnetic fields would be sensed by the at least one coil 14, 72. If an object impacted the outer skin 90 of the door 78 causing a physical deflection thereof, then this oscillating magnetic field would be perturbed at least in part by changes in the second magnetic field 104 caused by movement or deformation of the associated first conductive element 86 and the associated changes in the associated eddy currents 102 therein. If the impact is of sufficient severity, then the door beam 92 and the associated second conductive element 88 would also be moved or deformed thereby, causing additional and more substantial changes in the associated eddy currents 102 in the second conductive element 88 and the corresponding second magnetic field 104. Generally, the door beam 92 and associated second conductive element 88 would not be perturbed during impacts that are not of sufficient severity to warrant deployment of the associated safety restraint actuator 110, notwithstanding that there may be substantial associated deformation of the outer skin 90 of the door 78. Accordingly, in one embodiment, a magnetic crash sensor 10.1′″ might incorporate the second conductive element 88, and not the first conductive element 86.

Responsive to a crash with an impacting object of sufficient energy to deform the at least one conductive element 80, changes to the shape or position of the at least one conductive element 80 relative to the at least one coil 14, 72 affect the magnetic field affecting the at least one coil 14, 72. A resulting signal is preprocessed by the signal conditioner/preprocessor circuit 114, which provides for measuring the signal across the at least one coil 14, 72 and provides for measuring the signal applied thereto by the associated coil driver 96. The signal conditioner/preprocessor circuit 114—alone, or in combination with another processor 116—provides for decomposing the signal from the at least one coil 14, 72 into real and imaginary components, for example, using the signal applied by the associated coil driver 96 as a phase reference.

Whereas FIGS. 9 and 10 illustrate a magnetic crash sensor 10.1′″ mounted within a door 78 adapted to detect the deformation thereof responsive to an associated a side impact crash, it should be understood that the magnetic crash sensor 10.1′″ may be adapted to detect the intrusion, deformation, deflection or displacement of any conductive element 80, e.g. surface, in the vehicle 12 relative to a corresponding relatively fixed at least one coil 14, 72, for example, for detection of crashes involving other panels or either of the bumpers of the vehicle 12.

Referring to FIGS. 11 a and 11 b, a second embodiment of a coil 14.2 in accordance with the first aspect of the magnetic sensor 10.1 comprises a distributed coil 124 comprising a plurality of coil elements 14 formed with a printed circuit board 126 comprising a dielectric substrate 128 with a plurality of conductive layers 130 on opposing surfaces thereof, wherein each conductive layer 130 is adapted with associated planar conductive patterns 132, e.g. planar spiral conductive patterns 132′, for example, defining the associated coil elements L₁′, L₂′, L₃′ as illustrated. For example, the planar conductive patterns 132 on an associated dielectric substrate 128 may be formed by subtractive technology, for example, chemical or ion etching, or stamping; or additive techniques, for example, deposition, bonding or lamination. Adjacent coil elements L₁′, L₂′, L₃′ are located on opposite sides of the dielectric substrate 128, i.e. in different conductive layers 130, and are interconnected with one another in series by associated conductive vias 134 extending through the dielectric substrate 128. The coil elements 14 may be formed in multiple conductive layers 130, for example, with multiple associated dielectric substrates 128 if there were more than two conductive layers 130. Furthermore, the dielectric substrate 128 can be either rigid or flexible, the latter providing for a set of coil elements 14 adapted to conform to various surface geometries. Notwithstanding the different associated coil elements L₁′, L₂′, L₃′ illustrated in FIG. 11 a each have the same coil pitch sense, i.e. the same spiral winding sense so that each associated coil element L₁′, L₂′, L₃′ has the same polarity, it should be understood that the distributed coil 124 could be adapted with different coil elements L₁′, L₂′, L₃′ having different associated coil pitch senses.

Referring to FIG. 12, a third embodiment of a coil 14.3 in accordance with the first aspect of the magnetic sensor 10.1 comprises a distributed coil 124 comprising a plurality of coil elements 14 formed with a printed circuit board 126 comprising a dielectric substrate 128 with a conductive layer 130 on a surface thereof, wherein the conductive layer 130 is adapted with associated planar conductive patterns 132 defining an associated plurality of plurality of coil elements 14, each of which comprises substantially one turn with non-overlapping conductors 136, the plurality of which are connected in series.

Alternatively, the distributed coil 124 may comprise a plurality of coil elements 14, each comprising a winding of a conductor 136, e.g. magnet wire, wound so as to form either a planar or non-planar coil, and bonded to the surface of a substrate 138, wherein the associated coil elements 14 may be either separated from, or overlapping, one another, and the associated windings of a particular coil element 14 may be either overlapping or non-overlapping. The different coil elements 14 may be formed from a single contiguous conductor, or a plurality of conductive elements joined or operative together. The associated distributed coil 124 may comprise multiple layers either spanning across different sides of the substrate 138 or on a same side of the substrate 138. If the conductor 136 so formed were insulated, e.g. as would be magnet wire, then the substrate 138 could comprise substantially any material that would provide for the associated generation of the associated magnetic field 140 by the plurality of coil elements 14. Furthermore, the substrate 138 could comprise either a rigid material, e.g. a thermoset plastic material, e.g. a glass-epoxy composite material or a phenolic material; or a flexible material, e.g. a plastic or composite membrane.

The distributed coil 124 in accordance with any of the above-described embodiments may be encapsulated so as to provide for improved reliability and reduced susceptibility to environmental affects. Furthermore, the distributed coil 124 may be combined with some or all of the associated circuitry, e.g. the oscillator 98 and associated signal conditioner/preprocessor circuit 114, or components thereof, in an associated magnetic sensor module, some or all of which may be encapsulated so as to provide for improved reliability and reduced susceptibility to environmental affects. Alternatively, the distributed coil 124 and associated signal conditioner/preprocessor circuit 114 may be packaged separately.

Referring to FIG. 13, in a fourth embodiment of a coil 14.4 in accordance with the first aspect of the magnetic sensor 10.1, the substrate 138 is shaped, e.g. curved, so that different coil elements 14 are aligned in different directions 142, so as to provide for different magnetic field components 140 being oriented in different directions as necessary to provide for sensing a particular second portion 20, 82 of a vehicle 12.

Referring to FIGS. 14 a, 14 b, 15 a and 15 b one or more different second portions 20, 82 of the vehicle 12 being sensed may be adapted to cooperate at least one of the plurality of coil elements 14. For example, referring to FIGS. 14 a, 14 b, in accordance with a fifth embodiment of a coil 14.5 in accordance with the first aspect of the magnetic sensor 10.1, a conductive element 18, 80 is operatively associated with, or a part of, at least a second portion 20, 82 of the vehicle 12 being sensed so as to cooperate at least one of the plurality of coil elements 14, for example coil elements L₁′, L₂′, L₃′, so as to either provide for or control associated eddy currents 34, 102 in the conductive element 18, 80 responsive to the associated magnetic field components 140.1, 140.2 and 140.3 generated by the associated coil elements L₁′, L₂′, L₃′ proximate thereto. The magnetic axes 144 of the coil elements L₁′, L₂′, L₃′ are oriented so that the associated magnetic field components 140.1, 140.2 and 140.3 interact with the conductive element 18, 80 so as to generate associated eddy currents 34, 102 therein in accordance with Lenz's Law. The conductive element 18, 80 comprises, for example, a thin metal sheet, film or coating, comprising, for example, either a paramagnetic or diamagnetic material that is relatively highly conductive, e.g. aluminum or copper, and which, for example, could be an integral part of the associated second portion 20, 82 of the vehicle 12. For example, the conductive element 18, 80 could be spray coated onto the surface of the associated second portion 20, 82 of the vehicle 12. The frequency of the associated at least one time-varying signal applied to the associated coil elements L₁′, L₂′, L₃′ may be adapted so that the corresponding oscillating magnetic field components 140.1, 140.2 and 140.3 generated by the coil elements L₁′, L₂′, L₃′ provide for generating the associated eddy currents 34, 102 in the conductive element 18, 80. For example, the conductive element 18, 80 could be added to a non-metallic portion 146 of the vehicle 12 so as to provide for magnetic visibility thereof by the associated at least one of the plurality of coil elements 14.

A conductive element 18, 80 could also be added to a ferrous element 148, although in order for the affect of the magnetic field component(s) 140 to dominate an affect of a magnetic field within the ferrous element 148, the associated conductive element 18, 80 would need to be thick enough or conductive enough to prevent the original transmitted magnetic field component(s) 140 from penetrating though to the ferrous element 148 on the other side of the conductive element 18, 80, whereby eddy currents 34, 102 in the conductive element 18, 80 would completely cancel the magnetic field at some depth of penetration into the conductive element 18, 80. For example, for a superconducting conductive element 18, 80, there would be no penetration of the magnetic field component(s) 140 into the conductive element 18, 80. Although the depth of penetration of the first magnetic field 26, 94 increases as the conductivity of the conductive element 18, 80 decreases, an aluminum or copper conductive element 18, 80 would not need to be very thick (e.g. 2.5 mm or less) in order to substantially achieve this affect. The depth of penetration of magnetic fields into conductive elements 18, 80 is known from the art using eddy currents for non-destructive testing, for example, as described in the technical paper eddyc.pdf available from the internet at http://joe.buckley.net/papers, which technical paper is incorporated herein by reference. Generally, if the thickness of the conductive element 18, 80 exceeds about three (3) standard depths of penetration at the magnetic field frequency, then substantially no magnetic field will transmit therethrough. Responsive to a crash with an impacting object of sufficient energy to deform or translate the conductive element 18, 80, changes to the shape or position thereof relative to at least one of the coil elements L₁′, L₂′, L₃′ affects at least one of the associated magnetic field components 140.1, 140.2 and 140.3, which affect is detected by an associated signal conditioner/preprocessor circuit 114 operatively coupled to the coil elements L₁′, L₂′, L₃′ as described hereinabove.

The conductive element 18, 80 may comprise a pattern 150 adapted to control associated eddy currents 34, 102 therein. For example, the conductive element 18, 80 may be adapted by either etching, forming (e.g. which a sheet metal forming tool), coating (e.g. with an E-coat process), or machining the pattern 150 in or on a surface thereof so as to control, e.g. limit, the associated eddy currents 34, 102. The format, depth, and distribution of the pattern 150 can be optimized to provide optimal sensing resolution for a given operating frequency. The conductive element 18, 80 could be designed so that the movement or deformation thereof is highly visible to at least one of the plurality of coil elements 14 so as to increase the confidence of a timely associated crash or proximity detection. Each portion of the pattern 150 extends through at least a portion of the conductive element 18, 80 so as to provide for blocking or impeding eddy currents 34, 102 thereacross, so that the associated eddy currents 34, 102 become primarily confined to the contiguous conductive portions 152 therebetween or thereunder. For example, the pattern 150 may adapted to a frequency of the associated at least one time-varying signal.

Referring to FIGS. 15 a and 15 b, in accordance with a sixth embodiment of a coil 14.6 in accordance with the first aspect of the magnetic sensor 10.1, a conductive portion 154 of at least one of the portions 20, 76, 82 of the vehicle 12—for example, an inner surface of a body of the vehicle 12—adapted to cooperate with the plurality of coil elements 14 comprises a pattern 150 adapted to control associated eddy currents 34, 102 therein. The magnetic axes 144 of the coil elements L′ are oriented so that the associated magnetic field components 140 interact with the conductive portion 154 so as to generate associated eddy currents 34, 102 therein in accordance with Lenz's Law. The conductive portion 154 may be adapted, for example, by either etching, forming (e.g. which a sheet metal forming tool), coating (e.g. with an E-coat process), or machining a pattern 150 in or on a surface thereof so as to control, e.g. limit, the associated eddy currents 34, 102 therein. The format, depth, and distribution of the pattern 150 can be optimized to provide optimal sensing resolution for a given operating frequency. For example, a deterministic pattern 150′, such as the grid-etched pattern illustrated in FIG. 15 b may provide for distinguishing the associated portions 20, 76, 82 of the vehicle 12 responsive to displacement or deformation thereof. Each portion of the pattern 150 extends through at least a portion of the conductive portion 154 so as to provide for blocking or impeding eddy currents 34, 102 thereacross, so that the associated eddy currents 34, 102 become primarily confined to the contiguous conductive portions 156 therebetween or thereunder. For example, the pattern 150 may adapted to a frequency of the associated at least one time-varying signal.

A conductive element 158 may be adapted to cooperate with at least one of the plurality of coil elements 14 so as to provide for shaping, controlling or limiting at least one the associated magnetic field components 140. For example, referring to FIG. 16, in accordance with a seventh embodiment of a coil 14.7 in accordance with the first aspect of the magnetic sensor 10.1, at least one coil 14 is operatively coupled to a first side 160 of a substrate 138, and the conductive element 158 comprises a conductive layer 158′, e.g. a conductive film or plate spanning a portion of the opposite, second side 162 of the substrate 138, for example, as could be embodied with a printed circuit board 126. The conductive element 158 is relatively fixed with respect to the at least one coil 14 and provides for effectively shielding the at least one coil 14 proximate thereto from interference from proximate metal objects on the second side 162 of the substrate 138, so as to effectively provide for a non-sensing side 164 of the at least one coil 14 so shielded. The shielding action of the conductive element 158 results from eddy currents 34, 102 that are induced therein by the associated magnetic field components 140 of the associated at least one coil 14. The conductive layer 158′ could also be used to provide for shielding the at least one coil 14 from being responsive to localized deformations or intrusions of portions 20, 76, 82 of the vehicle 12 proximate thereto, for an at least one coil 14 adapted, either individually or in cooperation with another coil or magnetic sensing element, so as to provide for detecting changes to an associated magnetic circuit 68 over a relatively broad associated sensing area, without interference from localized deformations or intrusions, for example, in cooperation with the second aspect of the magnetic crash sensor 10.2 described hereinabove, or with embodiments disclosed in U.S. Pat. Nos. 6,777,927, 6,587,048, 6,586,926, 6,583,616, 6,631,776, 6,433,688, 6,407,660, each of which is incorporated herein by reference.

As another example, referring to FIGS. 17 a and 17 b, in accordance with an eighth embodiment of a coil 14.8 in accordance with the first aspect of the magnetic sensor 10.1, at least a portion of the conductive element 158 may be adapted to control or mitigate against eddy currents 34, 102 therein. For example, the conductive element 158 may be adapted, for example, by either etching, forming (e.g. with a sheet metal forming tool), or machining a pattern 150 in or on a surface thereof so as to control, e.g. limit, the associated eddy currents 34, 102 therein. The format, depth, and distribution of the pattern 150 can be optimized to provide optimal sensing resolution for a given operating frequency. Each portion of the pattern 150 extends through at least a portion of the conductive element 158 so as to provide for blocking or impeding eddy currents 34, 102 thereacross, so that the associated eddy currents 34, 102 become primarily confined to the contiguous conductive portions 156 therebetween or thereunder. For example, the pattern 150 may adapted to a frequency of the associated at least one time-varying signal. Furthermore, the depth of the pattern 150 may be adapted so that a plurality of contiguous conductive portions 156 are electrically isolated from one another.

Referring to FIG. 18, in accordance with a third aspect of a magnetic sensor 10.3 incorporated in a vehicle 12, at least one first coil 14 is located at a corresponding first location 166 of a body 168 of the vehicle 12. For example, the first coil 14 could be located around the striker 170.1 of the door latch assembly 172.1 of the front door 78.1, operatively coupled to the B-pillar 174 of the vehicle 12, or around a striker 170.2 of the door latch assembly 172.2 of the rear door 78.2 operatively coupled to the C-pillar 175 of the vehicle 12, or around a hinge 176 of a door 78, e.g. the front door 78.1. The at least one first coil 14 may also be located within a gap 178 between a fixed body structure and a door 78, e.g. the front door 78.1. Although FIG. 18 illustrates this first coil 14 located between the front edge 180 of the front door 78.1 and an adjacent edge 182 of the A-pillar 184, this first coil 14 could be located elsewhere in the gap 178 between either the front 78.1 or rear 78.2 door and the fixed body structure of the vehicle 12.

The at least one first coil 14 is operatively coupled to a corresponding coil driver 28, 56, 96, which is in turn operatively coupled to an oscillator 30, 58, 98, wherein an oscillatory signal from the oscillator 30, 58, 98 is applied by the coil driver 28, 56, 96 so as to cause an associated current in the first coil 14, responsive to which the first coil 14 generates a magnetic field 26, 140 comprising magnetic flux 186 in associated first 188.1 and second 188.2 magnetic circuits. The oscillator 30, 58, 98 generates a oscillating signal, for example, having either a sinusoidal, square wave, triangular or other waveform shape, of a single frequency, or a plurality of frequencies that are either stepped, continuously swept or simultaneous. The frequency is adapted so that the resulting magnetic field 26, 140 is conducted through the first 188.1 and second 188.2 magnetic circuits. For example, the oscillation frequency would typically be less than about 50 KHz for a steel structure, e.g. 10 to 20 KHz in one embodiment. The magnetic field 26, 140 is responsive to the reluctance

of the associated first 188.1 and second 188.2 magnetic circuits, which is affected by a crash involving the elements thereof and/or the gaps 178 therein. The magnetic flux 186 propagates within the associated magnetically permeable material of the first 188.1 and second 188.2 magnetic circuits. The doors 78.1, 78.2 are isolated from the remainder of the vehicle 12, e.g. the frame, by the gaps 178 therebetween, except where the hinges 176 and door latch assemblies 172.1, 172.2 provide relatively lower reluctance paths therebetween.

The at least one first coil 14 can each be used alone in a single-port mode to both generate the magnetic flux 186 and to detect a signal responsive thereto, and may also be used in cooperation with one or more magnetic sensors 190 in a multi-port mode. For example, one or more first coils 14 at corresponding first locations 166 can be used in cooperation with a plurality of magnetic sensors 190.1, 190.2 at a corresponding plurality of second locations 192.1, 192.2 of the vehicle 12. For example, for a first coil 14 located around the striker 170.1 of the door latch assembly 172.1 of the front door 78.1, in one embodiment, the magnetic sensors 190.1, 190.2 comprise a second coil 194 around a hinge 176 of the front door 78.1, and a third coil 196 around a striker 170.2 of the door latch assembly 172.2 of the rear door 78.2 and the striker 170.2 of the door latch assembly 172.2 of the rear door 78.2 is operatively coupled to the C-pillar 175 of the vehicle 12. The second 194 and third 196 coils surround metallic elements of the associated first 188.1 and second 188.2 magnetic circuits, and the magnetic flux 186 propagating within the associated magnetically permeable material of the first 188.1 and second 188.2 magnetic circuits also flows through the second 194 and third 196 coils surrounding the associated magnetically permeable material. The second 194 and third 196 coils generate voltage signals responsive to the oscillating magnetic flux 186, or component thereof, directed along the axis of the second 194 and third 196 coils respectively, in accordance with Faraday's law of magnetic induction.

In operation in accordance with a single-port mode, a time varying signal 198 is generated by a signal source 200, for example, and oscillator or a pulse generator, and applied to the at least one first coil 14 by an associated coil driver 202. For example, an oscillatory signal source 200 would function similar to that described hereinabove for any of oscillators 30, 58 and 98, and the coil driver 202 would function similar to that described hereinabove for any of coil drivers 28, 56 and 96, depending upon the particular application. The two leads of the at least one first coil 14 define a port A_(i), which is also connected to an associated signal conditioner/preprocessor circuit 114 which processes a signal associated with the at least one first coil 14, the signal being responsive to the time varying signal 198 applied thereto, and responsive to the self-impedance of the associated at least one first coil 14. As disclosed more fully hereinbelow, the coil driver 202 can be incorporated into the circuitry of the associated signal conditioner/preprocessor circuit 114. The at least one first coil 14 generates a magnetic field 26, 140 in and throughout the associated magnetic circuit 188.1, 188.2, responsive to the time varying signal 198 applied thereto. For example, for an at least one first coil 14 located within a gap 178 between a fixed body structure and a proximal surface of another element of the body provides for detecting a relative movement between the fixed body structure and the proximal surface, responsive to a crash, for example, responsive to an intrusion of the proximal surface relative to the fixed body structure.

In a two-port mode, one or more associated magnetic sensors 190, 190.1, 190.2 at respective second locations 192.1, 192.2 are operatively coupled at a port B_(j) to a corresponding one or more signal conditioner/preprocessor circuits 40, which provide for generating a signal responsive to the magnetic field 26, 140 at the corresponding one or more second locations 192.1, 192.2.

The signal conditioner/preprocessor circuit(s) 114, 40 are operatively coupled to an associated processor 204, and provide for conditioning the associated signal(s) from the at least one first coil 14 and one or more associated magnetic sensors 190, 190.1, 190.2. The signal conditioner/preprocessor circuit(s) 114, 40 demodulate the signal(s) from the associated at least one first coil 14 or one or more associated magnetic sensors 190, 190.1, 190.2 with an associated demodulator, and converts from analog to digital form with an associated analog-to-digital converter which is sampled and input to the processor 204. The signal conditioner/preprocessor circuit(s) 114, 40 may also provide for amplification. Changes to the magnetic field 26, 140 at a particular location in the first 188.1 and second 188.2 magnetic circuits propagate therewithin at the speed of light and are seen therethroughout. Accordingly, the magnetic field 26, 140 sensed by the at least one first coil 14, and possibly by one or more associated magnetic sensors 190.1, 190.2, contains information about the nature of the remainder of the magnetic circuit, including the front 78.1 and rear 78.2 doors and the adjacent A-pillar 184, B-pillar 174 and C-pillar 175, any of which could be involved in, or affected by, a crash, responsive to which the processor 204 provides for detecting the crash and controlling a safety restraint actuator 44 responsive thereto. In FIG. 18, the ports of the various first coils 14 and magnetic sensors 190 illustrated therein are labeled as “A or B” to indicate that that particular first coil 14 or magnetic sensor 190 could be connected to either of ports port A_(i) or B_(j) of the associated signal processing circuitry, depending upon the particular sensing configuration, provided that at least one first coil 14 is connected to a corresponding at least one port A_(i). For example, the system could be configured to operate with only one or more first coils 14 in a single-port mode, for example, as disclosed herein, or in accordance with U.S. Pat. Nos. 6,587,048, 6,583,616 or 6,433,688, each of which is incorporated herein by reference. Alternatively, the system could be configured to also operate with one or more associated magnetic sensors 190.1, 190.2 in a multi-port mode, for example, in accordance with U.S. Pat. Nos. 6,777,927, 6,586,926, 6,631,776 or 6,433,688, each of which is incorporated herein by reference.

Referring to FIG. 19, the fragmentary view 1900 of the A-pillar 184 and front door 78.1 from FIG. 18 is illustrated in greater detail, illustrating several possible embodiments of the at least one first coil 14 in greater detail, two of which comprise a gap coil 206 that is sufficiently small to be located within the gap 178 between the A-pillar 184 and the front door 78.1. The gap coil 206 of the at least one first coil 14 is not necessarily constrained to surround existing magnetic permeable components of the first 188.1 or second 188.2 magnetic circuits, so as to provide for placement of the gap coil 206 in locations without being adversely constrained by the geometries or functions of proximate elements of the vehicle 12. The gap coil 206 is wound around an associated spool 208 which is fastened to the fixed structure of the vehicle, e.g. the edge 182 of the A-pillar 184 facing the front edge 180 of the front door 78.1. The gap coil 206 can be oriented to as to optimize the signal-to-noise ratio of the signal generated thereby responsive to a crash or other disturbance to be monitored.

For example, in a ninth embodiment of a coil 14.9, the axis 210 of the gap coil 206 is substantially perpendicular to the edge 182 of the A-pillar 184 and to the front edge 180 of the front door 78.1 when the front door 78.1 is closed. The coil 14.9 is attached to the A-pillar 184 with a fastener 212 through the associated spool 208, e.g. a socket head screw 212.1 through a counterbore in the spool 208. The magnetic permeability of the fastener 212 can be adapted in accordance with the sensing or field generating requirements of the associated gap coil 206. For example, the fastener 212 associated with the coil 14.9 is substantially aligned with the axis 210 of the gap coil 206, so that a fastener 212 of a material with a relatively high permeability, e.g. carbon steel or electrical steel, will tend to concentrate the magnetic flux 186 through the gap coil 206, whereas a fastener 212 of a material with a relatively low permeability, e.g. stainless steel, aluminum or brass, will tend to emulate an air core so that the coil 14.9 has less of a tendency to perturb the associated first 188.1 or second 188.2 magnetic circuit. As another example, in a tenth embodiment of a coil 14.10, the axis 210 of the gap coil 206 is substantially parallel to the edge 182 of the A-pillar 184 and to the front edge 180 of the front door 78.1, so as to be substantially aligned with the length of the associated gap 178. The coil 14.10 is shown attached to the A-pillar 184 with a fastener 212 through a flange that depends from the associated spool 208.

FIG. 19 also illustrates an embodiment of the at least one first coil 14 around a hinge 176 of the front door 78.1. Referring to FIG. 20, the at least one first coil 14 can be located at various first 166′, 166″, 166″ or second 192.1′, 192.1″, 192.1′″ locations relative to the hinge 176. For example, in one embodiment, the first 166′ or second 192.1′ location is on around a portion of the hinge plate 176.1 that attaches to the fixed vehicle structure, e.g. the A-pillar 184 or B-pillar 174, at a location between the A-pillar 184 or B-pillar 174 and the hinge joint 176.2. In another embodiment, the first 166″ or second 192.1″ location is on around a portion of the hinge plate 176.1 that attaches to the fixed vehicle structure, e.g. the A-pillar 184 or B-pillar 174, at a location where the hinge plate 176.1 is bolted to the A-pillar 184 or B-pillar 174. In yet another embodiment, the first 166′″ or second 192.1′″ location is on around a portion of the hinge plate 176.3 that attaches to the front 78.1 or rear 78.2 door, at a location between the front edge 180 of the front 78.1 or rear 78.2 door and the hinge joint 176.2.

Referring to FIG. 21, a gap coil 206 may be mounted on the B-pillar 174 or C-pillar 175 on an outward facing surface 214 in the gap 178 between the outward facing surface 214 and a corresponding proximate inward facing surface 216 of the front 78.1 or rear 78.2 door respectively. In the embodiment illustrated in FIG. 21, the gap coil 206 is secured to the outward facing surface 214 with a flat head screw 212.2 through the spool 208 around which the coil is wound. The gap coil 206 illustrated in FIG. 21 is responsive to changes in reluctance of the associated first 188.1 or second 188.2 magnetic circuit responsive to the door opening state of the associated front 78.1 or rear 78.2 door and accordingly can be used to generate a signal indicative thereof, e.g. so as to provide for discriminating between a closed door, a partially latched door and an open door.

Referring to FIG. 22, a gap coil assembly 218 comprises a gap coil 206 wound around a spool 208, both of which are encapsulated in an encapsulant 220, e.g. a silicone potting compound, so as mitigate against environmentally induced degradation. The gap coil 206 for example, is wound of wire, e.g. 10 to 50 gauge enamel coated conductive wire, e.g. copper or aluminum. The spool 208 is, for example, made of a relatively rigid material such as plastic or aluminum.

Referring to FIG. 23, the gap coil assembly 218 can further comprise a core 222 of a material having relatively high magnetic permeability such as ferrite, mu-metal, or amorphous metal, e.g. METGLAS®.

The gap coil assemblies 218 illustrated in FIGS. 22 and 23 can be mounted, for example, by bonding or clamping. Referring to FIG. 24, the gap coil assembly 218 is mounted with a fastener 212, e.g. a cap screw 212.3 and washer 224, through a central mounting hole 226 in the spool 208. The material and dimensions of the fastener 212 would be selected according to the particular application. A material having relatively high magnetic permeability such as carbon steel or electrical steel could be used to concentrate the associated magnetic flux 186 through the gap coil 206, whereas a material of relatively low magnetic permeability such as aluminum, brass or stainless steel could be used to emulate an air core, thereby having less influence on the inherent flow of magnetic flux 186 across the associated gap 178 within which the gap coil assembly 218 is located.

Referring to FIG. 25, the gap coil assembly 218 is mounted with a fastener 212, e.g. a socket head screw 212.1, and further incorporates a magnetically permeable core 228 comprising a shouldered sleeve 230 that is recessed within the central mounting hole 226 in the spool 208. For example, the magnetically permeable core 228 can comprise either carbon steel, electrical steel, mu-metal, ferrite, or amorphous metal, e.g. METGLAS®. The length of the shouldered sleeve 230 can be adjusted in relation to the associated gap 178 in which the gap coil assembly 218 is mounted depending upon the extent of associated magnetic focusing required.

Referring to FIGS. 26 a and 26 b, modeling and test results suggest that eddy currents I_(E) are produced on the surface of steel pins or fasteners 212, strikers 170.1, 170.2, and hinges 176, wherein the eddy currents I_(E) oscillate longitudinally along the associated steel core 232, producing an associated circumferential magnetic field B_(E) surrounding the axes of the associated steel core 232. Referring to FIGS. 27 and 28, a toroidal helical coil 234 provides for generating a voltage signal V responsive to the associated oscillating circumferential magnetic field B_(E) in accordance with Faraday's Law, responsive to which an associated current signal I is generated when the toroidal helical coil 234 is connected to an associated circuit, e.g. a signal conditioner/preprocessor circuit 114. The toroidal helical coil 234 comprises a conductive path 236, e.g. a winding of conductive wire 236.1, e.g. copper or aluminum wire, around a toroidal core 238. Although the toroidal core 238 is illustrated in FIGS. 27 and 28 as having a circular shape (FIG. 27) and a uniform circular cross section (FIG. 28)—i.e. doughnut shaped—, in general the, the toroidal core 238 can have any closed shape with any cross-sectional shape, either uniform or not. For example, the toroidal core 238 could have a rectangular cross-section, similar to that of a washer. The toroidal core 238 comprises a major axis M and a minor axis m, wherein the conductive path 236 makes at least one turn around the minor axis m, and at least one turn around the major axis M. For example, in the embodiment illustrated in FIG. 27, the conductive path 236 makes a plurality of turns around the minor axis m, and a single turn around the major axis M. The at least one turn around the minor axis m provides for generating a component of the voltage signal V responsive to an oscillating circumferential magnetic field B_(E), and the at least one turn around the major axis M provides for generating a component of the voltage signal V responsive to an oscillating axial magnetic field B_(C), the latter of which is illustrated in FIGS. 26 a and 26 b. Accordingly, the toroidal helical coil 234 can be used to sense both axial B_(C) and circumferential B_(E) magnetic fields. The doughnut-shaped toroidal core 238 illustrated in FIGS. 27 and 28 comprises a major radius R, a minor radius r, and an associated outside b and inside a radii and a minor diameter 2 r, and may be constructed of either a ferromagnetic or a non-ferromagnetic material, depending upon the application, i.e. whether or not it is necessary to concentrate circumferential magnetic flux within the toroidal core 238. For example, referring to FIG. 28, a toroidal helical coil assembly 240 comprises a toroidal helical coil 234 encapsulated in an encapsulant 220 about a central mounting hole 226 adapted to receive an associated fastener 212, e.g. a cap screw 212.3. The modeling and testing done with a toroidal helical coil 234 suggests that the eddy currents I_(E) (and therefore the associated circumferential magnetic field B_(E)) are substantially enhanced when the steel core 232 associated with the toroidal helical coil 234 is electrically connected to the front 78.1 or rear 78.2 doors and/or the vehicle frame, whereby an electrical connection to both, e.g. via a hinge 176, is beneficial. Tests have indicated that a stronger signal may be obtained when using a toroidal helical coil 234 instead of a circular wound gap coil 206 at a location otherwise suitable for a gap coil assembly 218.

The signal from the signal conditioner/preprocessor circuit 114 responsive to the at least one coil 14 may be used to detect changes to the associated magnetic circuit 188 to which the at least one coil 14 is operatively associated. Generally, the changes to the associated magnetic circuit 188 comprise a combination of effects, including 1) changes to the reluctance

of the magnetic circuit 188 to which the at least one coil 14 is magnetically coupled, and 2) eddy currents 34, 102 induced in a proximal conductive element 88 responsive to a first magnetic field 26, 94 generated by the at least one coil 14, which generate a first magnetic field 26, 94 in opposition to the first magnetic field 26, 94, thereby affecting the self-induced voltage in the at least one coil 14.

Referring to FIG. 29, a particular coil element L′ is driven by an oscillatory time-varying voltage signal v operatively coupled thereto through an associated sense resistor R_(S). The oscillatory time-varying voltage signal v generates an associated oscillatory current i in the associated series circuit 242 which generates an associated magnetic field component 140 that interacts with an associated second portion 20, 82 of the vehicle 12. If the associated second portion 20, 82 of the vehicle 12 is conductive, then the associated magnetic field component 140 interacting therewith will generate associated eddy currents 34, 102 therein in accordance with Faraday's Law of induction. The direction of the associated eddy currents 34, 102 is such that the resulting associated eddy-current-induced magnetic field component 38, 104 opposes the associated magnetic field component 140 generated by the current i in the coil element L′. If the associated second portion 20, 82 of the vehicle 12 is not perfectly conductive, then the eddy currents 34, 102 will heat the associated conductive material resulting in an associated power loss, which affects the relative phase of the eddy-current-induced magnetic field component 38, 104 relative to the phase of the oscillatory time-varying voltage signal v. Furthermore, a ferromagnetic associated second portion 20, 82 of the vehicle 12 interacting with the associated magnetic field component 140 can affect the self-inductance L of the associated coil element L′.

Referring to FIGS. 30 and 31, the impedance Z of the coil element L′ is illustrated as a function of the transverse position x of the coil element L′ relative to a crack 244 extending into in a conductive second portion 20, 82 of the vehicle 12, for various crack depths d, with the coil element L′ at a constant distance y from the conductive second portion 20, 82 of the vehicle 12, wherein the distance y is the length of the gap between the coil element L′ and the surface of the conductive second portion 20, 82 of the vehicle 12. In FIG. 31, the inductive reactance X_(L) and resistance R_(L) components of impedance Z of the coil element L′ are plotted in the complex plane as a function of transverse position x for families of crack depth d, wherein the resistance R_(L) of the coil element L′ is responsive to a component of the current i that is in-phase with respect to the associated time-varying voltage signal v, and the inductive reactance X_(L) of the coil element L′ is responsive to a component of the current i that is in quadrature-phase with respect to the associated time-varying voltage signal v. Relative to the nominal impedance Z₀=(X₀, R₀) of the coil element L′, corresponding to a negligible perturbation from the crack 244, the effective inductive reactance X_(L) of the coil element L′ increases, and the effective resistance R_(L) decreases, with increasing crack depth d and with increasing proximity to the crack 244 (i.e. decreasing transverse (x) distance with respect to the crack 244). The eddy-current-induced magnetic field component 38, 104 opposing the magnetic field component 140 responsive to the current i therein causes the nominal decrease in the effective impedance Z of the coil element L′ relative to free-space conditions, and the crack 244 disrupts the eddy currents 34, 102 in the conductive second portion 20, 82 of the vehicle 12 causing a resulting increase in effective impedance Z. Similarly, the effective impedance Z of the coil element L′ is a function of the distance y from, and the magnetic and conductive properties of, the conductive second portion 20, 82 of the vehicle 12. The at least one coil 14 provides for substantially generating a corresponding at least one measure responsive to the impedance Z of each associated coil element L′, which provides for detecting an associated change in the magnetic condition of the vehicle 12 over or within an associated sensing region associated with the at least one coil element 14, which is responsive to changes in the gap distance y to the associated proximate second portion 20, 82 of the vehicle 12, and responsive to changes in the magnetic and conductive properties thereof and to changes in the reluctance

of the associated magnetic circuit 188.

The signal conditioner/preprocessor circuit 114 provides for detecting the impedance Z of at least one coil element 14, or of a combination or combinations of a plurality of coil elements 14. For example, referring to FIG. 32, a Maxwell-Wien bridge 246 may be used to measure the inductive reactance X_(L) and resistance R_(L) components of impedance Z of a coil element L′ or a combination of coil elements L′. Alternatively, the signal conditioner/preprocessor circuit 114, provides for measuring at least one signal across a coil element L′ or a combination of the coil elements L′ and provides for measuring the signal applied thereto by the associated coil driver 202. The signal conditioner/preprocessor circuit 114—alone, or in combination with the processor 204, provides for decomposing the signal from the coil element L′ or a combination of the coil elements L′ into real and imaginary components, for example, using the signal applied by the associated coil driver 202 as a phase reference.

The coil element L′, or a combination of the coil elements L′, is/are magnetically coupled, either directly or indirectly, to at least a portion of the vehicle 12 susceptible to deformation responsive to a crash, wherein changes thereto (e.g. deformation thereof) responsive to a crash affects the reluctance

of the associated magnetic circuit 68, 188, and/or induces eddy currents 34, 102 in an associated proximal conductive element 18, either of which affects the current i in the coil element L′, or a combination of the coil elements L′, detection of which provides for detecting the resulting associated change in the magnetic condition of the vehicle 12 associated with the deformation of the associated portion of the vehicle 12 responsive to the crash.

Referring to FIG. 33, a coil 14 of a magnetic crash sensor 10.1, 10.1′, 10.1″, 10.1′″ or 10.3 is illustrated in proximity to a proximal conductive element 80 located a distance x from the coil 14 and subject to a crash-responsive movement 248 relative to the coil 14. The coil 14 driven with a time-varying current source 250 generates a first magnetic field 26, 94 which induces eddy currents 34, 102 in the conductive element 80, which in turn generate a second magnetic field 38, 104. A voltage signal V is generated across the coil 14 responsive to the self-inductance L and intrinsic resistance R_(L) thereof, and responsive to induction from the second magnetic field 38, 104. Referring to FIG. 34, the phasor value of the resulting complex voltage signal V can be decomposed into a first signal component 252 given by C₁+C₂·x  (1) which includes a bias component C₁ and a displacement component C₂·x responsive to static displacement x of the conductive element 80 relative to the coil 14; and a second signal component 254 given by:

$\begin{matrix} {C_{3} \cdot \frac{\partial x}{\partial t}} & (2) \end{matrix}$ which is responsive to the velocity of the conductive element 80 relative to the coil 14, wherein the phasor phase values of the first 252 and second 254 signal components are referenced with respect to the drive current signal I_(dr) applied by the time-varying current source 250 and are orthogonal with respect to one another in the complex plane. It is hypothesized that the velocity dependent second signal component 254 is related to the momentum transferred to the vehicle 12 by the object or other vehicle in collision therewith, and that the displacement component C2·x is related to the energy absorbed by the vehicle 12 during the crash, wherein relatively soft vehicles 12 would tend to absorb relatively more energy and would tend to produce relatively more low frequency signals, and relatively stiff vehicles 12 would tend to receive relatively more momentum and would tend to produce relatively more high frequency signals. Furthermore, the real component 256 of the complex voltage signal V is related to the resistive losses in the coil 14 or the eddy current losses in the conductive element 80, whereas the imaginary component 258 is related to the self-inductance of the coil 14 which is responsive to the permeability of the magnetic elements inductively coupled therewith.

Referring to FIG. 35, in accordance with a first aspect of a signal conditioning circuit 294, the coil 14 is in series combination with a balanced pair of sense resistors R_(S1), R_(S2) in a series circuit 242 is driven by a coil driver 28, 56, 96 fed with a time varying signal 198 from an oscillator 30, 58, 98, wherein a first terminal of a first sense resistor R_(S1) is coupled at a first node 260 of the series circuit 242 to a first output terminal 262 of the coil driver 28, 56, 96, a second terminal of the first sense resistor R_(S1) is coupled at a second node 264 of the series circuit 242 both to a first sense terminal 266 of the coil driver 28, 56, 96 and to a first terminal of the coil 14, a second terminal of the coil 14 is coupled at a third node 268 of the series circuit 242 both to a second sense terminal 270 of the coil driver 28, 56, 96 and to a first terminal of a second sense resistor R_(S2), and a second terminal of the second sense resistor R_(S2) is coupled at a fourth node 272 of the series circuit 242 to a second output terminal 274 of the coil driver 28, 56, 96. For example, the time varying signal 198 is sinusoidal having a frequency between 10 KHz and 100 KHz, and is DC biased with a common mode voltage so a to provide for operation of the associated circuitry using a single-ended power supply. The AC signals of the outputs from the first 262 and second 274 output terminals of the coil driver 28, 56, 96 are of opposite phase with respect to one another, and the coil driver 28, 56, 96 is adapted so as to control these output signals so that the peak-to-peak AC voltage V_(L) across the coil 14 sensed across the first 266 and second 270 sense terminals of the coil driver 28, 56, 96 is twice the peak-to-peak AC voltage V_(AC) of the oscillator 30, 58, 98. The coil driver 28, 56, 96 is further adapted to substantially null any DC current component through the coil 14 so as to prevent a magnetization of the vehicle 12 by the first magnetic field 26, 94 generated by the coil 14. The first 260, second 264, third 268 and fourth 272 nodes, having corresponding voltages V₁, V₂, V₃ and V₄ respectively, are coupled to input resistors R₁, R₂, R₃ and R₄ of a summing and difference amplifier 276 implemented with an operational amplifier 278, a resistor R₅ from the non-inverting input 280 thereof to a DC common mode voltage signal V_(CM) and to a ground through a capacitor C_(G), thereby providing for an AC ground, and a resistor R₆ between the inverting input 282 and the output 284 thereof, wherein input resistors R₁ and R₃ are coupled to the non-inverting input 280, and input resistors R₂ and R₄ are coupled to the inverting input 282.

The first 266 and second 270 sense terminals of the coil driver 28, 56, 96 are of relatively high impedance, so that the first R_(S1) and second R_(S2) sense resistors and the coil 14 each carry substantially the same current I from the coil driver 28, 56, 96. The voltage V_(out) at the output 284 of summing and difference amplifier 276 is given as: V _(out)=(V ₁ −V ₄)−(V ₂ −V ₃)=I·(R _(S1) +R _(S2))  (3) which is equal to the total voltage drop across the sense resistors R_(S1), R_(S2), which provides a measure of the current through the coil 14. Accordingly, given that the voltage V_(L) across the coil 14 is controlled to a value of twice the peak-to-peak AC voltage V_(AC) of the oscillator 30, 58, 98, and is therefore known, the measure of current I through the coil 14—responsive to V_(out)—can be used in combination with the known voltage V_(L) across the coil 14, to determine the self-impedance Z of the coil 14. Alternatively, the current I through the coil 14 can be demodulated into in-phase I and quadrature-phase Q components phase-relative to the sinusoidal time varying signal 198 of the oscillator 30, 58, 98 so as to provide substantially equivalent information, wherein the in-phase component I provides a measure of the effective resistance R of the coil 14, and the quadrature-phase component Q provides a measure of the effective impedance Z of the coil 14. In accordance with this latter approach, the output 284 of the summing and difference amplifier 276 is filtered by a low-pass filter 286, converted from analog to digital form by an analog-to-digital converter 288, and demodulated into the in-phase I and quadrature-phase Q components by a demodulator 290 which is phase-referenced to the time varying signal 198 of the oscillator 30, 58, 98.

The in-phase I and/or quadrature-phase Q component, individually or in combination, is/are then processed by a crash sensing algorithm 292 in the processor 108, 204 to provide for discriminating or detecting crash events that are sufficiently severe to warrant the deployment of the safety restraint actuator 44. For example, in one set of embodiments, the in-phase component I, possibly in combination with the quadrature-phase Q component, is processed to provide for discriminating or detecting crash events that are sufficiently severe to warrant the deployment of the safety restraint actuator 44. Alternatively, the in-phase component I, possibly in combination with the quadrature-phase Q component, may be used to provide a safing signal to prevent the actuation of a safety restraint actuator 44 absent a crash of sufficient severity to warrant a possible deployment thereof.

Referring to FIG. 36, the self-impedance Z_(L) of a coil 14, L′, or the associated self-resistance R_(L) or self-inductance L_(L) thereof, may be determined using a first embodiment of a signal conditioning circuit 294.1 wherein a time-varying voltage V_(AC) is applied by an oscillator 296 across the series combination of a sense resistor R_(S) and the coil 14, L′. The current i_(L) through the series combination, and therefore through the coil 14, L′, is given by the ratio of the complex or phasor voltage V_(R) across sense resistor R_(S), divided by the value R_(S) of the sense resistor R_(S), wherein the voltage V_(R) is measured as either a magnitude and a phase relative to the applied time varying voltage V_(AC), or by demodulation into in-phase I and quadrature-phase Q components relative to the applied time varying voltage V_(AC). The self-impedance Z_(L) of the coil 14, L′ is then given from Ohms Law as the ratio of the voltage V_(L) across the coil 14, L′, i.e. V_(L)=V_(AC)−V_(R), divided by the current i_(L) through the coil 14, L′, or:

$\begin{matrix} {Z_{L} = {\frac{R_{S} \cdot V_{L}}{V_{R}} = \frac{R_{S} \cdot \left( {V_{AC} - V_{R}} \right)}{V_{R}}}} & (4) \end{matrix}$

Referring to FIG. 37, in accordance with a second embodiment of a signal conditioning circuit 294.2 that provides for generating one or more measures responsive to the self-impedance Z_(L) of a coil 14, L′, a balanced time varying voltage V_(AC)′ is applied by an oscillator 298 across the series combination of the coil 14, L′ and two sense resistors R_(S1), R_(S2) in a balanced architecture, wherein the sense resistors R_(S1), R_(S2) are of substantially equal value, the coil 14, L′ is coupled between the sense resistors R_(S1), R_(S2), and the remaining terminals of the sense resistors R_(S1), R_(S2) are coupled to first 298.1 and second 298.2 terminals of the oscillator 298 which provide for complementary output signals V_(A)′ and V_(B)′ respectively, each of which has a substantially zero-mean value and is of substantially opposite phase to the other. For example, in one embodiment, the output signal V_(A)′ is given by A·sin(ωt) and the output signal V_(B)′ is given by −A·sin(ωt), wherein A is the peak amplitude and ω is the associated radian frequency, so that the time varying voltage V_(AC)′ is given by V_(AC)′=V_(A)′−V_(B)′=2·A·sin(ωt). The balanced feed and architecture provides for reduced EMI (Electromagnetic Interference) susceptibility and emissions. The self-impedance Z_(L) of the coil 14, L′ is given from Equation (1) by substituting therein V_(AC)′ for V_(AC), and (V_(R1)+V_(R2)) for V_(R), wherein V_(R1) and V_(R2) are the measured voltages across the respective sense resistors R_(S1), R_(S2).

Referring to FIG. 38, a third embodiment of a signal conditioning circuit 294.3 that provides for generating one or more measures responsive to the self-impedance Z_(L) of a coil 14, L′ is similar to the second embodiment illustrated in FIG. 37, with the exception of the incorporation of an oscillator 300 adapted to provide for single-ended complementary output signals V_(A) and V_(B), so as to provide for operation with associated single-ended electronic devices, i.e. where all signals are between 0 and +V_(max) volts. For example, each of the output signals V_(A) and V_(B) is biased by a DC common mode voltage signal V_(CM), so that V_(A)=V_(CM)−A·sin(ωt) and V_(B)=V_(CM)−A·sin(ωt), wherein, in one embodiment for example, V_(CM)=V_(max)/2 and the peak amplitude A is less than or equal to V_(CM). In one embodiment, the oscillator 300 comprises a digital clock generator and sine/cosine shaper that generates digital complementary signals which are converted to analog form with a digital-to-analog converter to generate the complementary output signals V_(A) and V_(B).

Referring to FIG. 39, in accordance with a fourth embodiment of a signal conditioning circuit 294.4 that provides for generating one or more measures responsive to the self-impedance Z_(L) of a coil 14, L′, the voltage V_(L) across the coil 14, L′ is controlled by using feedback control of the signals applied to the first 260 and fourth 272 nodes at the sense resistors R_(S1), R_(S2) in series with the coil 14, L′ responsive to feedback signals from the second 264 and third 268 nodes across the coil 14, L′. More particularly, the first complementary output signal V_(A) is fed through a first input resistor R_(A1) to the inverting input of a first operational amplifier 302, which is also coupled through a first feedback resistor R_(A2) to the second node 264 where the first sense resistor R_(S1) is coupled to a first terminal of the coil 14, L′. Furthermore, the second complementary output signal V_(B) is fed through a second input resistor R_(B1) to the inverting input of a second operational amplifier 304, which is also coupled through a second feedback resistor R_(B2) to the third node 268 where the second sense resistor R_(S2) is coupled to the second terminal of the coil 14, L′. The output 262 of the first operational amplifier 302 is coupled to the first node 260 at the first sense resistor R_(S1), and the output 274 of the second operational amplifier 304 is coupled to the fourth node 272 at the second sense resistor R_(S2). A first common mode voltage signal V_(CM1) is coupled to the non-inverting input of the first operational amplifier 302, and a second common mode voltage signal V_(CM2) is coupled to the non-inverting input of the second operational amplifier 304.

For ideal first 302 and second 304 operational amplifiers, and for:

$\begin{matrix} {\frac{R_{A\; 2}}{R_{A\; 1}} = {\frac{R_{B\; 2}}{R_{B\; 1}} = \alpha}} & (5) \\ {V_{{CM}\; 1} = {V_{{CM}\; 2} = V_{CM}}} & (6) \\ {{V_{A} = {V_{CM} - {A \cdot {\sin\left( {\omega\; t} \right)}}}},\;{and}} & (7) \\ {V_{B} = {V_{CM} + {A \cdot {\sin\left( {\omega\; t} \right)}}}} & (8) \end{matrix}$

the voltage V_(L) across the coil 14, L′ is given by: V _(L) =V ₂ −V ₃=α·(V _(B) −V _(A))=2·α·A·sin(ωt)  (8)

Accordingly, the feedback control loop provides for controlling the value of the voltage V_(L) across the coil 14, L′, and, for example, setting this to a value higher than would be obtained, for example, with the third embodiment of the signal conditioning circuit 294.3 illustrated in FIG. 38, so as to provide for higher signal levels and correspondingly higher associated signal-to-noise ratios. For example, with α=1, the voltage V_(L) across the coil 14, L′ would be V_(B)-V_(A), whereas in the third embodiment of the signal conditioning circuit 294.3 illustrated in FIG. 38, this is the value of the voltage applied across the series combination of the sense resistors R_(S1), R_(S2) and the coil 14, L′. The first 302 and second 304 operational amplifiers control the voltage V_(L) across the coil 14, L′, the current i_(L) through the coil 14, L′ is responsive to the self-impedance Z_(L) of the coil 14, L′, i.e. (i_(L)=V_(L)/Z_(L)), and the voltages at the first 260 and fourth 272 nodes are automatically set by the first 302 and second 304 operational amplifiers so as to provide the current necessary to control the voltage V_(L) across the coil 14, L′. However, the currents through the first R_(S1) and second R_(S2) sense resistors will not correspond exactly to the current i_(L) through the coil 14, L′ because of the currents i_(RA2) and i_(RB2) through the first R_(A2) and second R_(B2) feedback resistors, and the corresponding signal from Equation (3) used to measure the current i_(L) through the coil 14, L′ is given by:

$\begin{matrix} {{V_{out} = {{\left( {V_{1} - V_{4}} \right) - \left( {V_{2} - V_{3}} \right)}\mspace{40mu} = {\left( {R_{S\; 1} + R_{S\; 2}} \right) \cdot \left( {i_{L} + {\frac{1}{2} \cdot \left( {i_{{RA}\; 2} - i_{{RB}\; 2}} \right)}} \right)}}}{{wherein}\text{:}}} & (9) \\ {{i_{{RA}\; 2} = \frac{V_{2} - V_{CM}}{R_{A\; 2}}},{and}} & (10) \\ {i_{RB2} = \frac{V_{3} - V_{CM}}{R_{B2}}} & (11) \end{matrix}$

Referring to FIG. 40, in accordance with a fifth embodiment of a signal conditioning circuit 294.5 that provides for generating one or more measures responsive to the self-impedance Z_(L) of a coil 14, L′, the affect of the currents i_(RA2) and i_(RB2) through the first R_(A2) and second R_(B2) feedback resistors can be mitigated by using third 306 and fourth 308 operational amplifiers configured as respective buffer amplifiers 306′, 308′ so as to provide for substantially eliminating any loading by the first R_(A2) and second R_(B2) feedback resistors on the second 264 and third 268 nodes, respectively, so that the current through each of the sense resistors R_(S1), R_(S2) is substantially the same as the current i_(L) through the coil 14, L′. Accordingly, the signal from Equation (3) used to measure the current i_(L) through the coil 14, L′ is representative thereof and is given by: V _(out)=(V ₁ −V ₄)−(V ₂ −V ₃)=(R _(S1) +R _(S2))·i _(L)  (12)

The remaining portions of the signal conditioning circuit 294.5 function the same as for the fourth embodiment of the signal conditioning circuit 294.4 illustrated in FIG. 39, except that the first 302 and second 304 operational amplifiers are illustrated as real operational amplifiers rather than ideal operational amplifiers, wherein respective DC bias voltage sources δ₁ and δ₂ are added to the non-inverting inputs thereof, respectively, to provide for simulating the affects of internal biases associated with real operational amplifiers. Accordingly, for the conditions of Equations (5), (7) and (8), the voltage V_(L) across the coil 14, L′ is given by: V ₁ =V ₂ −V ₃=α·(V _(B) −V _(A))+(1+α)·((V _(CM1) −V _(CM2))+(δ₁−δ₂))  (13)

Under the conditions of Equation (6), this reduces to: V _(L) =V ₂ −V ₃=α·(V _(B) −V _(A))+(1+α)·(δ₁−δ₂)  (14)

Under the conditions of Equations (7) and (8), this reduces to: V _(L) =V ₂ −V ₃=2·α·A·sin(ωt)+(1+α)·(δ₁−δ₂)  (15)

The AC component of the voltage V_(L) across the coil 14, L′ has a value of: V _(L) ^(AC)=(V ₂ −V ₃)^(AC)=2·α·A·sin(ωt),  (16) which, for α=1, is comparable to that of third embodiment of the signal conditioning circuit 294.3 illustrated in FIG. 38.

Accordingly, the DC bias voltage sources δ₁ and δ₂ cause the voltage V_(L) across the coil 14, L′ to have a DC bias of: (1+α)·(δ₁−δ₂),  (17) which, for α=1 and δ=max(|δ₁|,|δ₂|), can have a value as great as 4δ—because the DC bias voltage sources δ₁ and δ₂ are uncorrelated—which causes a corresponding DC bias current in the coil 14, L′, which might adversely magnetize the vehicle 12.

Referring to FIG. 41, in accordance with a sixth embodiment of a signal conditioning circuit 294.6 that provides for generating one or more measures responsive to the self-impedance Z_(L) of a coil 14, L′, the fifth embodiment of the signal conditioning circuit 294.5 illustrated in FIG. 40 is modified with the inclusion of a fifth operational amplifier 310 adapted to provide for operating on the voltage V_(L) across the coil 14, L′, so as to provide for nulling DC biases therein. More particularly, the non-inverting input of the fifth operational amplifier 310 is coupled through a third input resistor R₂₂ to the output of the third operational amplifier 306, and is also coupled through a fourth input resistor R_(CM1) to the first common mode voltage signal V_(CM1). The inverting input of the fifth operational amplifier 310 is coupled through a fifth input resistor R₃₂ to the output of the fourth operational amplifier 308, and is also coupled through a second feedback resistor R_(CM2) to the output of the fifth operational amplifier 310 and to the non-inverting input of the second operational amplifier 304 so as to provide the second common mode voltage signal V_(CM2) thereto.

Letting:

$\begin{matrix} {{\frac{R_{{CM}\; 2}}{R_{32}} = {\frac{R_{{CM}\; 1}}{R_{22}} = G}},} & (16) \end{matrix}$ the second common mode voltage signal V_(CM2) is then given by: V _(CM2) V _(CM1) +G·(V ₂ −V ₃)+(1+G)·δ₅,  (17) and the resulting voltage V_(L) across the coil 14, L′ is then given by:

$\begin{matrix} {{V_{L} = {{V_{2} - V_{3}}\mspace{31mu} = \frac{{{\alpha \cdot \left( {V_{B} - V_{A}} \right)} + \left( {1 + \alpha} \right)}{\cdot \left( {\delta_{1} - \delta_{2} - {\left( {1 + G} \right) \cdot \delta_{5}}} \right)}}{1 + {\left( {1 + \alpha} \right) \cdot G}}}},} & (18) \end{matrix}$ wherein a prospective DC offset of the fifth operational amplifier 310 is represented by a DC bias voltage source δ₅ at the non-inverting input thereof.

For the first V_(A) and second V_(B) complementary output signals given by Equations (7) and (8) respectively, the resulting voltage V_(L) across the coil 14, L′ is given by:

$\begin{matrix} {V_{L} = {\frac{{{2 \cdot \alpha \cdot A \cdot {\sin\left( {\omega\; t} \right)}} + \left( {1 + \alpha} \right)}{\cdot \left( {\delta_{1} - \delta_{2}} \right)}}{1 + {\left( {1 + \alpha} \right) \cdot G}} - {\frac{\left( {1 + \alpha} \right){\cdot \left( {1 + G} \right)}}{1 + {\left( {1 + \alpha} \right) \cdot G}} \cdot \delta_{5}}}} & (19) \end{matrix}$

For α=1, the resulting voltage V_(L) across the coil 14, L′ is given by:

$\begin{matrix} {V_{L} = {\frac{{2 \cdot A \cdot {\sin\left( {\omega\; t} \right)}} + {2 \cdot \left( {\delta_{1} - \delta_{2}} \right)} - \delta_{5}}{1 + {2 \cdot G}} - \delta_{5}}} & (20) \end{matrix}$

Accordingly, as the gain G is increased, the magnitude of the first component of Equation (20)—which includes the entire AC component and the DC components attributable to the DC bias voltage sources δ₁ and δ₂—decreases. For example, for G=1, the voltage V_(L) across the coil 14, L′ is given by: V _(L) =A·sin(ωt)+(δ₁−δ₂)−1.5·δ₅, and  (21) and as the gain G approaches infinity, the voltage V_(L) across the coil 14, L′ approaches the value of the DC bias voltage source δ₅ associated with the fifth operational amplifier 310: V_(L)=−δ₅.  ((22)

Accordingly, with sufficient gain G, the sixth embodiment of the signal conditioning circuit 294.6 illustrated in FIG. 41 provides for reducing the affect of the DC bias voltage sources δ₁ and δ₂ on the voltage V_(L) across the coil 14, L′, but at the expense of also reducing that magnitude of the associated AC signal component.

Referring to FIG. 42, in accordance with a seventh embodiment of a signal conditioning circuit 294.7 that provides for generating one or more measures responsive to the self-impedance Z_(L) of a coil 14, L′, the affect of the DC bias voltage sources 61 and 62 on the voltage V_(L) across the coil 14, L′ may be reduced without adversely affecting the associated AC signal component by modifying the fifth operational amplifier 310 to act as a low pass filter, for example, by adding a feedback capacitor C_(F1) between the output and the inverting input of the fifth operational amplifier 310, across the second feedback resistor R_(CM2), the combination of which forms an low-pass filter circuit 312, which acts to reduce the gain G with increasing frequency. The cutoff frequency of the low-pass filter circuit 312 is set substantially lower than the operating frequency of the oscillator 300. For example, in one embodiment, the cutoff frequency of the low-pass filter circuit 312 is set at least two decades below the operating frequency of the oscillator 300. The seventh embodiment of a signal conditioning circuit 294.7 further comprises a low-pass filter 314 between the output of the fifth operational amplifier 310 and the non-inverting input of the second operational amplifier 304, for example, comprising a series resistor R_(F2) and a parallel capacitor C_(F2). As illustrated in FIG. 42, filter capacitors C_(F3) and C_(F4) may be respectively added from the non-inverting and inverting inputs of the fifth operational amplifier 310, each to ground, respectively, so as to increase the order of the associated low-pass filter circuit 312.

The seventh embodiment of the signal conditioning circuit 294.7 illustrated in FIG. 42 is unable to compensate for the affect of prospective respective DC bias voltage sources 63 and/or δ₄, if any, of the third 306 and/or fourth 308 operational amplifiers, respectively, on the voltage V_(L) across the coil 14, L′. Referring to FIG. 43, in accordance with an eighth embodiment of a signal conditioning circuit 294.8 that provides for generating one or more measures responsive to the self-impedance Z_(L) of a coil 14, L′, this limitation, and a similar limitation in the sixth embodiment of the signal conditioning circuit 294.6 illustrated in FIG. 41, may be remedied by coupling the non-inverting input of the fifth operational amplifier 310 through the third input resistor R₂₂ to the first node 260 of the series circuit 242, rather than to the output of the third operational amplifier 306; and by coupling the inverting input of the fifth operational amplifier 310 through the fifth input resistor R₃₂ to the fourth node 272 of the series circuit 242, rather than to the output of the fourth operational amplifier 308. Accordingly, the fifth operational amplifier 310 and associated circuitry of the eighth embodiment of a signal conditioning circuit 294.8 provides for nulling a DC bias of the voltage across the first 260 and fourth 272 nodes of the series circuit 242, associated with a DC bias of the current i_(L) therethrough. In comparison, the seventh embodiment of the signal conditioning circuit 294.7 acts to null the DC bias voltage across the third 264 and fourth 268 nodes of the series circuit 242. The eighth embodiment of a signal conditioning circuit 294.8 is effective because even though the voltages across the third 264 and fourth 268 nodes and the first 260 and fourth 272 nodes are generally different when the current i_(L) is non-zero, both of these voltages will equal to zero when the current i_(L) through the series circuit 242 is equal to zero.

Referring to FIG. 44, in accordance with a ninth embodiment of a signal conditioning circuit 294.9 that provides for generating one or more measures responsive to the self-impedance Z_(L) of a coil 14, L′, as an alternative to the seventh embodiment of the signal conditioning circuit 294.7 illustrated in FIG. 42, the fifth operational amplifier 310 is configured as an integrator 316, wherein the non-inverting input of the fifth operational amplifier 310 is coupled through the third input resistor R₂₂ to the output of the third operational amplifier 306, and is also coupled to ground through a filter capacitor C_(F3). The inverting input of the fifth operational amplifier 310 is coupled through the fifth input resistor R₃₂ to the output of the fourth operational amplifier 308, and is also coupled through an integrator capacitor C₁ to the output of the fifth operational amplifier 310 and through an output resistor R₁ to the non-inverting input of the second operational amplifier 304, the latter of which is also coupled through a sixth input resistor R_(CM2′) to the first DC common mode voltage signal V_(CM1). Accordingly, a DC bias in the voltage V_(L) across the coil 14, L′ is integrated by the integrator 316 so as to generate the second common mode voltage signal V_(CM2) at the non-inverting input of the second operational amplifier 304 so as to provide compensation therefore, so as to provide for reducing or eliminating the DC bias in the voltage V_(L) across the coil 14, L′.

Referring to FIG. 45, a tenth embodiment of a signal conditioning circuit 294.10 that provides for generating one or more measures responsive to the self-impedance Z_(L) of a coil 14, L′, is based upon the embodiment illustrated in FIG. 35 described hereinabove, wherein the coil driver 28, 56, 96 comprises a circuit based upon the seventh embodiment of a signal conditioning circuit 294.7 illustrated in FIG. 42, together with an example of circuitry for generating the output signals V_(A) and V_(B) from the associated oscillator 300. For example, the low-pass filter 312 can be as described in accordance with the seventh embodiment of a signal conditioning circuit 294.7.

The tenth embodiment of the signal conditioning circuit 294.10 further illustrates an example of a circuit 317 for generating the first common mode voltage signal V_(CM1). For example, the circuit 317 comprises a first voltage divider 318 of resistors R₇ and R₈ fed by a supply voltage source V_(S). The output of the voltage divider 318 is buffered by an associated sixth operational amplifier 320 configured as an associated buffer amplifier 320′. For example, for resistors R₇ and R₈ of equal value, the resulting first common mode voltage signal V_(CM1) would be half the value of the supply voltage source V_(S).

The tenth embodiment of the signal conditioning circuit 294.10 further illustrates an example of an embodiment of the associated oscillator 300, wherein the output signal V_(A) is generated by a seventh operational amplifier 322, the non-inverting input of which is coupled to the output of a second voltage divider 324 comprising resistors R₉ and R₁₀ fed by the first common mode voltage signal V_(CM1), the inverting input of which is coupled by an input resistor R₁₁ to an oscillator 30, 58, 98, and by a feedback resistor R₁₂ to the output of the seventh operational amplifier 322. For resistors R₉ and R₁₀ of equal value, and for resistors R₁₁ and R₁₂ of equal value, and for the output of the oscillator 30, 58, 98 given by A·sin(ωt), then the output signal V_(A) is given by Equation (7).

Furthermore, the output signal V_(B) is generated by an eighth operational amplifier 326, the non-inverting input of which is coupled to the first common mode voltage signal V_(CM1) through a first input resistor R₁₃, and to the oscillator 30, 58, 98 through a second input resistor R₁₄; and the non-inverting input of which is coupled by a an input resistor R₁₅ to ground, and by a feedback resistor R₁₆ to the output of the eighth operational amplifier 326. For resistors R₁₃ and R₁₄ of equal value, and for resistors R₁₅ and R₁₆ Of equal value, and for the output of the oscillator 30, 58, 98 given by A·sin(ωt), then the output signal V_(B) is given by Equation (8).

Referring to FIG. 46, an eleventh embodiment of a signal conditioning circuit 294.11 that provides for generating one or more measures responsive to a self-impedance Z_(L) of a coil 14, L′, is substantially based upon the tenth embodiment of the signal conditioning circuit 294.10 illustrated in FIG. 45, wherein like reference signs correspond to similar elements which function as described hereinabove, and FIG. 45 includes supplemental aspects as described hereinbelow. In accordance with a second embodiment of an oscillator 300′, a sine shaper 328 driven by a clock 330 generates a digital time series 334 of a sine wave, for example, with 8-bit digital sample values, which is fed into a digital-to-analog converter 332 which generates a corresponding sampled analog sine wave waveform, which is in turn filtered by a low-pass filter 336 to remove artifacts of the associated quantization and sampling processes, such as associated harmonics and clocking noise associated with the digital-to-analog converter 332. For example, in one embodiment, the sine shaper is programmable from 15.6 kilohertz to 44.9 kilohertz, and the resulting analog sine wave has a 0.8 volt peak-peak magnitude. The filtered sine wave signal 338 from the low-pass filter 336 is fed into an oscillator signal conditioner 340 adapted to generate the single-ended first V_(A) and second V_(B) complementary output signals, for example, as described hereinabove, for example, in accordance with the circuitry associated with the seventh 322 and eighth 324 operational amplifiers and associated circuitry described hereinabove in association with the tenth embodiment of the signal conditioning circuit 294.10 illustrated in FIG. 45. The first 302 and second 304 operational amplifiers provide for a linear driver 342 that drives the coil 14, L′ with a sine wave responsive to the first V_(A) and second V_(B) complementary output signals, wherein the associated gain α thereof given by Equation (5) is programmable responsive to the processor 108, 204 by adjustment of the associated input R_(A1), R_(B1) and feedback R_(A2), R_(B2) resistors associated with the first 302 and second 304 operational amplifiers. For example, each of the input R_(A1), R_(B1) and feedback R_(A2), R_(B2) resistors can be adjusted by switching a corresponding network of resistors interconnected with associated FET transistors, or using an FET transistor as a variable resistor. For example, in one embodiment, the processor 108, 204 is adapted to adjust the current i_(L) through the coil 14, L′ so as to be within the range of 10-50 milliamperes RMS, by adjusting the gain α of the linear driver 342, wherein in the eleventh embodiment of the signal conditioning circuit 294.11, the corresponding voltage from the linear driver 342 is within the range of 0.8 to 64 volts peak-to-peak in 0.8 volt steps, responsive to a corresponding range of gain α of 1 to 80 volts/volt. The common mode voltage signal V_(CM) is generated by an associated circuit 317, for example, as illustrated in FIG. 45, which in one embodiment is adjustable responsive to the processor 108, 204, for example, so as to provide for a common mode voltage signal V_(CM) that is adjustable between 2.4 and 21 volts in 0.6 volt steps, so as to prevent saturation of the linear driver 342.

As with the embodiments illustrated in FIGS. 39-45, the voltage V_(L) across the coil 14, L′ is controlled by using the first 302 and second 304 operational amplifiers to provide for feedback control of the signals applied to the first 260 and fourth 272 nodes at the sense resistors R_(S1), R_(S2) in series with the coil 14, L′ responsive to feedback signals from the second 264 and third 268 nodes across the coil 14, L′.

Furthermore, a bias control circuit 344 provides for substantially nulling any DC current bias in the current i_(L) through the coil 14, L′. For example, in accordance with a first aspect of a bias control circuit 344.1, for example, as illustrated in FIGS. 41, 42, 44 and 45 hereinabove, and in FIGS. 59, 61 and 63 hereinbelow, this is provided by the circuitry associated with the fifth operational amplifier 310 thereof, which provides for using feedback 345.1 responsive to voltages V₂, V₃ at the second 264 and third 268 nodes of the series circuit 242, i.e., across the coil 14, L′ therewithin, to generate either a) a first aspect of a control signal 347.1 that is applied to the non-inverting input of the second operational amplifier 304, which controls the voltage V₄ at the fourth node 272 of the series circuit 242 so as to substantially null the DC current bias in the current i_(L) through the coil 14, L′; or b) a second aspect of control signals 347.2 that are applied to the oscillator signal conditioner 340 to the inverting inputs of the first 302 and second 304 operational amplifier 304, in opposite senses respectively, which controls the voltages V₁, V₄ at the first 260 and fourth 272 nodes of the series circuit 242 respectively, so as to substantially null the DC current bias in the current i_(L) through the coil 14, L′. The first aspect of the bias control circuit 344.1 utilizes feedback 345.1 responsive to a voltage signal across the coil 14 L′ within the series circuit 242, and accordingly is also referred to herein as “inner voltage feedback”, which provides for nulling the current i_(L) through the coil 14, L′ by nulling the voltage thereacross.

In accordance with a second aspect of a bias control circuit 344.2, for example, as illustrated in FIG. 43 hereinabove, and in FIGS. 62 and 63 hereinbelow, feedback 345.2 responsive to voltages V₁, V₄ at the first 260 and fourth 272 nodes of the series circuit 242, i.e. across the series circuit 242, is used to generate either a) the first aspect of the control signal 347.1 that is applied to the non-inverting input of the second operational amplifier 304, which controls the voltage V₄ at the fourth node 272 of the series circuit 242 so as to substantially null the DC current bias in the current i_(L) through the coil 14, L′; or b) the second aspect of control signals 347.2 that are applied to the oscillator signal conditioner 340 to the inverting inputs of the first 302 and second 304 operational amplifier 304, in opposite senses respectively so as to substantially null the DC current bias in the current i_(L) through the coil 14, L′. The second aspect of the bias control circuit 344.2 utilizes feedback 345.2 responsive to a voltage signal across the series circuit 242, and accordingly is also referred to herein as “outer voltage feedback”, which provides for nulling the current i_(L) through the coil 14, L′ by nulling the voltage across the series circuit 242.

Yet further, as with the embodiments illustrated in FIGS. 35 and 45, the eleventh embodiment of the signal conditioning circuit 294.11 incorporates a sum-and-difference amplifier circuit 346 comprising an operational amplifier 278 and associated circuitry, which provides for generating an output voltage V_(out) responsive to the sum of the voltage drops across the sense resistor R_(S1), R_(S2), which provides a measure of the current i_(L) through the coil 14, L′, i.e. a current measure 348. For example, in one embodiment, the sum-and-difference amplifier circuit 346 is nominally unity gain. The sense resistor R_(S1), R_(S2) are adapted so as to provide for an output voltage V_(out) of about 0.8 volts peak-to-peak under nominal operating conditions.

In accordance with a third aspect of a bias control circuit 344.3, for example, as illustrated in FIGS. 54-56, 59 and 61 hereinbelow, feedback 345.3 responsive to the voltage V_(out) at the output 284 of summing and difference amplifier 276, i.e. associated with the current measure 348, is used to generate either a) the first aspect of the control signal 347.1 that is applied to the non-inverting input of the second operational amplifier 304, which controls the voltage V₄ at the fourth node 272 of the series circuit 242 so as to substantially null the DC current bias in the current i_(L) through the coil 14, L′; or b) the second aspect of control signals 347.2 that are applied to the oscillator signal conditioner 340 to the inverting inputs of the first 302 and second 304 operational amplifier 304, in opposite senses respectively so as to substantially null the DC current bias in the current i_(L) through the coil 14, L′. The third aspect of the bias control circuit 344.3 utilizes feedback 345.3 responsive to the voltage V_(out) associated with the current measure 348 that provides a measure of the current i_(L) through the coil 14, L′, and accordingly is also referred to herein as “current feedback”, which provides for nulling the current i_(L) through the coil 14, L′ by nulling the voltage V_(out) associated with the current measure 348.

The voltage V_(out) providing a measure of the current i_(L) through the coil 14, L′ is filtered with a band-pass filter 350 and then converted to digital form with an associated first analog-to-digital converter 288′. For example, in one embodiment, the band-pass filter 350 is a second order two-input fully differential switched capacitor bandpass filter having a Butterworth approximation, and a programmable center frequency that, responsive to the processor 108, 204, is automatically set to the same frequency as that of the sine shaper 328 and associated clock 330. In this embodiment, the band-pass filter 350 has a fixed 6 kiloHertz passband and is used to limit the susceptibility to out-of-band energy radiated from other sources.

A ninth operational amplifier 352 configured as a differential amplifier provides for measuring the actual voltage across the voltage V_(L) across the coil 14, L′, notwithstanding that this is otherwise controlled by the circuitry associated with the linear driver 342 and bias control circuit 344 as described hereinabove. More particularly, the second node 264 coupled to a first terminal of the coil 14, L′, at a voltage V₂, is coupled through a first input resistor R₂₃ to the non-inverting input of the ninth operational amplifier 352, which is also connected to the DC common mode voltage signal V_(CM) ground through a resistor R₂₄. Furthermore, the third node 268 coupled to the second terminal of the coil 14, L′, at a voltage V₃, is coupled through a second input resistor R₃₃ to the inverting input of the ninth operational amplifier 352, which is also connected to the output thereof a feedback resistor R₃₄. Accordingly, the output of the ninth operational amplifier 352, designated as voltage V_(OUT), is given as follows: V _(Drive)=γ·(V ₂ −V ₃)  (23) wherein the gain γ is given by:

$\begin{matrix} {\gamma = {\frac{R_{24}}{R_{23}} = \frac{R_{34}}{R_{33}}}} & (24) \end{matrix}$

In various embodiments, for example, the gain γ may be programmable responsive to the processor 108, 204. For example, in one embodiment, the gain γ is programmable over a range of 1 to 80 volts/volt, so that the resulting voltage V_(Drive) from the ninth operational amplifier 352 is within the range of 0-1 volt peak-to-peak for input to an associated second analog-to-digital converter 354.

Referring to FIGS. 46-47, as an example of one embodiment, the first 288′ and second 354 analog-to-digital converters are each embodied with corresponding first 356.1 and second 356.2 sigma-delta analog-to-digital converters, each comprising the combination of a sigma-delta converter 358, followed by a low-pass sync filter 360, followed by a decimation filter 362. Referring to FIGS. 47 and 49, the sigma-delta converter 358 is a separately clocked circuit that provides for converting a given signal level into a corresponding single-bit Pulse Density Modulated (PDM) signal. For a time-varying input signal, the clocking rate of the sigma-delta converter 358 is substantially higher than the corresponding sampling rate of the associated time-varying input signal, so that the time-varying input signal is effectively over-sampled. For example, in one embodiment, for a time-varying input signal with a sampling rate between 10 and 50 kiloHertz, the clock rate of the sigma-delta converter 358 is set at 4 megaHertz. In accordance with the embodiment of a sigma-delta converter 358 illustrated in FIG. 47, the current value of the output Vout_(n) of the sigma-delta converter 358 is subtracted at a first summing junction 364 from the current value of the input signal Vin_(n), and the result is scaled by a gain of ½ and integrated by a first integrator 366. The current value of the output Vout_(n) of the sigma-delta converter 358 is then subtracted at a second summing junction 368 from the most recent updated value of the output VINT1 _(n+1) of the first integrator 366, and the result is scaled by a gain of ½ and integrated by a second integrator 370. The most recent updated value of the output VINT2 _(n+1) of the second integrator 370 is then input to a comparator 372, the output, which is the output Vout_(n+1) of the sigma-delta converter 358, has a value of zero if the most recent updated value of the output VINT2 _(n+1) of the second integrator 370 is less than one, and otherwise has a value of one, and which is buffered by a buffer amplifier 373 and then converted to analog form with a one-bit digital-to-analog converter 374 and then fed back therefrom to the first 364 and second 368 summing junctions, wherein the comparator 372, buffer amplifier 373 and one-bit digital-to-analog converter 374 can be combined together in practice. The above-described operation of the sigma-delta converter 358 is modeled by the following equations, which provide for converting a signal having a magnitude between zero and one volt:

$\begin{matrix} {{{VINT}\; 1_{n + 1}} = {{{VINT}\; 1_{n}} + {\frac{1}{2} \cdot \left( {{Vin}_{n} - {Vout}_{n}} \right)}}} & (25) \\ {{{VINT}\; 2_{n + 1}} = {{{VINT}\; 2_{n}} + {\frac{1}{2} \cdot \left( {{{VINT}\; 1_{n + 1}} - {Vout}_{n}} \right)}}} & (26) \\ {{Vout}_{n + 1} = \begin{Bmatrix} 0 & {{if}\mspace{14mu}\left( {{{VINT}\; 2_{n + 1}} < 1} \right)} \\ 1 & {{if}\mspace{14mu}\left( {{{VINT}\; 2_{n + 1}} \geq 1} \right)} \end{Bmatrix}} & (27) \end{matrix}$

Referring to FIGS. 48 a-d, the output Vout_(n) of a sigma-delta converter 358 in accordance with Equations (25)-(27) is plotted as a function of internal clock cycle n for four different corresponding DC input voltages of 0.10, 0.25, 0.50 and 0.75 volts, respectively. It should be understood that output Vout_(n) of a sigma-delta converter 358 is binary, with a value of zero or one, and that the ramped portions of the plots of FIGS. 48 a-d are artifacts of the plotting process. The average value of each of the one-bit (i.e. binary valued) time series illustrated in FIGS. 48 a-d is equal to the value of the corresponding DC input voltage, wherein the pulse density modulation level of each time series is equal to the value of the corresponding DC input voltage.

In one embodiment, the sigma-delta converter 358 is implemented with a fully differential second-order switched-capacitor architecture, using a sampling rate of 4 megahertz, with a usable differential input range of 0-1 volt peak-to-peak. In one embodiment, the sigma-delta converter 358 is principally used at about one half of full scale in order to avoid distortion from the one-bit digital-to-analog converter 374 which can occur for input signals have a magnitude greater than about eighty percent of full scale. Above full scale, the one-bit digital-to-analog converter 374 would overload, causing a loss of signal integrity. Using only half of full scale to avoid distortion, the sigma-delta converter 358 would have an effective gain of 0.5, although this can be compensated for in the associated decimation filter 362 which, for example, in one embodiment, is adapted to utilize a twelve-bit span for a one volt peak-to-peak input signal.

Referring to FIGS. 46 and 49, the output of a first sigma-delta converter 358.1 associated with the first sigma-delta analog-to-digital converter 356.1 is filtered with a first low-pass sync filter 360.1 and then decimated with a first decimation filter 362.1, so as to generate the digital representation—in one embodiment, for example, a twelve-bit representation—of the voltage V_(out). For example, in one embodiment the first low-pass sync filter 360.1 and the first decimation filter 362.1 are embodied in a first decimator 382.1 structured in accordance with the decimator 382 illustrated in FIG. 49, which comprises a plurality of accumulators 384 followed by a plurality of differentiators 386 ganged together in series with a corresponding plurality of summing 388 and difference 390 junctions.

The number of bits needed in the accumulators 384 to avoid overflow errors is defined by: w=K·log ₂(N)+b  (28) wherein K is the decimator order (e.g. 3), N is the decimation ratio (e.g. 128), and b is the number of bits entering the decimator (e.g. 1 or 8). For example, for K=3, N=128 and b=1, the accumulators 384 are 22 bits wide, whereas for b=8, the accumulators 384 would be 29 bits wide. Each of the accumulators 384 is defined by the following equation: Vacc_(n+1) =Vacc_(n) +Vin_(n)  (29)

For example, for an input clock rate of 4 megahertz, the output of the last accumulator 384 illustrated in FIG. 49 would be sampled at 31.25 kilohertz. The output of the last accumulator 384 is then fed into the differentiators 386, which have the same number of bits as defined by Equation (28). Each of the differentiators 386 are defined by the following equation: Vdiff_(n+1) =Vin_(n+1) −Vin_(n)  (30)

For example, in one embodiment, the output of the last differentiators 386 of the first 382.1 and second 382.2 decimators is truncated to twelve bits. The mixing process associated with the first and second mixers inherently has a gain of ½ (as a result of an associated ½ cosine factor), and this is compensated in the decimator 382 so that the twelve-bit span of the digital output thereof corresponds to a one volt peak-to-peak signal at the input to the sigma-delta converter 358. The associated generic equation of the decimator 382 is given by: f=[(1−z _(−N))/(1−z ⁻¹)]^(K)  (31)

Referring to FIG. 50, the operation of a sigma-delta analog-to-digital converter 356 is illustrated by a power spectrum in the frequency domain, as described in the article “Demystifying Sigma-Delta ADCs”, downloadable from the Internet at http://www.maxim-ic:com/appnotes.cfm/appnote_number/1870, and which is incorporated herein by reference in its entirety. The oversampling process of the sigma-delta converter 358 increases the signal-to-noise ratio (SNR), and the first 366 and second integrators 370 act as a highpass filter to the noise 392, and act to reshape the noise 392 as illustrated in FIG. 50. The low pass sync filter 360 in the time domain acts as a notch filter 394 in the frequency domain, which provides for removing a substantial portion of the noise 392 while preserving the signal 396.

Referring again to FIG. 46, the output from the first decimation filter 362.1 is operatively coupled to first 376.1 and second 376.2 demodulators which demodulate the signal therefrom into in-phase (I) and quadrature (Q) phase components of the voltage V_(out) representative of the current i_(L) through the coil 14, L′. The first demodulator 376.1 uses the digital time series 332 from the sine shaper 328 to demodulate the in-phase (I) component of the voltage V_(out) down to a corresponding DC level, albeit the pulse density modulated (PDM) equivalent thereof, wherein, for example, in one embodiment, the digital time series 332 from the sine shaper 328 is fed into an associated first mixer 376.1′ of the first demodulator 376.1 as an N-bit stream at the same over-sampled clock rate (e.g. 4 megahertz) as the signal from the first sigma-delta converter 358.1, so as to provide a measure representative of the in-phase (I) component of the current i_(L) through the coil 14, L′. The second demodulator 376.2 uses a digital time series 378 from a cosine shaper 380 to demodulate the quadrature-phase (Q) component of the voltage V_(out) down to a corresponding DC level, albeit the pulse density modulated (PDM) equivalent thereof, wherein, for example, in one embodiment, the digital time series 378 from the cosine shaper 380 is fed into an associated second mixer 376.2′ of the second demodulator 376.2 as an N-bit stream at the same over-sampled clock rate (e.g. 4 megahertz) as the signal from the first sigma-delta converter 358.1 of the quadrature-phase (Q) component of the voltage V_(out), so as to provide a measure representative of the quadrature-phase (Q) component of the current i_(L) through the coil 14, L′. The cosine shaper 380 is driven in synchronism with the sine shaper 328 by a common signal from the clock 330, responsive to the processor 108, 204. For example, in one embodiment, the N-bit streams from the sine 328 and cosine 380 shapers are eight-bit streams.

The outputs of the first 376.1 and second 376.2 demodulators are respectively filtered by respective first 398.1 and second 398.2 low-pass filters, and are then respectively filtered by respective first 400.1 and second 400.2 band-pass filters. For example, in one embodiment, the first 398.1 and second 398.2 low-pass filters are second order digital filters with a programmable type (e.g. Butterworth or Chebyshev) and programmable filter coefficients k and gain factors G, the same type and values for each filter 398.1, 398.2; and the first 400.1 and second 400.2 band-pass filters are fourth order digital filters with a programmable type (e.g. Butterworth or Chebyshev) and programmable coefficients, the same type and values for each filter 400.1, 400.2. The gain factors G in each filter are adapted to provide for unity gain through each of the filters 398.1, 398.2, 400.1, 400.2. For example, the filter coefficients k and gain factors G are stored in a twelve-bit register in fixed point two's complement number format.

For example, the first 398.1 and second 398.2 low-pass filters are given generally by the following transfer function:

$\begin{matrix} {{{H(z)} = {G\left\lbrack \frac{1 + {2z^{- 1}} + z^{- 2}}{1 - {k_{1}z^{- 1}} + {k_{2}z^{- 2}}} \right\rbrack}},\mspace{14mu}{and}} & (32) \end{matrix}$ the first 400.1 and second 400.2 band-pass filters are given generally by the following transfer function:

$\begin{matrix} {{H(z)} = {G_{1}{G_{2}\left\lbrack \frac{\left( {1 - z^{- 2}} \right)^{2}}{\left( {1 - {k_{1}z^{- 1}} + {k_{2}z^{- 2}}} \right)\left( {1 + {k_{3}z^{- 1}} + {k_{4}z^{- 2}}} \right)} \right\rbrack}}} & (33) \end{matrix}$

In one embodiment, the outputs of the first 400.1 and second 400.2 band-pass filters are averaged using a four point averaging process, for example, using a running average implemented with a moving window, so as to provide resulting in-phase (I) and quadrature (Q) phase components of the voltage V_(out) representative of the current i_(L) through the coil 14, L′ at an update rate of about 7.8 kilohertz. In the present embodiment, the low-pass filters 398.1, 398.2 would not be used below 300 Hertz because of stability problems due to quantization errors in the associated gain factors G and filter coefficients k. The resulting in-phase I and quadrature-phase Q data can be used to calculate, with twelve-bit accuracy, the magnitude of the and phase of the current i_(L) through the coil 14, L′, as follows:

$\begin{matrix} {{Magnitude} = \sqrt{I^{2} + Q^{2}}} & (34) \\ {{Phase} = {\arctan\left( \frac{Q}{I} \right)}} & (35) \end{matrix}$ wherein the phase is quadrant-corrected so that the resulting phase value is between −180° and +180°, with 0° on the positive I axis, 90° on the positive Q axis.

The output of a second sigma-delta converter 358.2 associated with the second sigma-delta analog-to-digital converter 356.2 is filtered with a second low-pass sync filter 360.2 and then decimated with a second decimation filter 362.2, so as to generate the digital representation—in one embodiment, for example, a twelve-bit representation—of the voltage V_(Drive), representative of the voltage V_(L) across the coil 14, L′. For example, in one embodiment the second low-pass sync filter 360.2 and the second decimation filter 362.2 are embodied in a second decimator 382.2, similar to the first decimator 382.1 described hereinabove, except that the output thereof is a ten-bit digital word. The output of the second decimator 382.2 is operatively coupled to a second demodulator 376.2 which demodulates an over-sampled signal (e.g. at 4 megahertz) from the second sigma-delta converter 358.2 into an in-phase component (I) of the voltage V_(Drive) across the coil 14, L′. The second demodulator 376.2 uses the digital time series 332 from the sine shaper 328 to demodulate the in-phase (I) component of the voltage V_(Drive) down to a corresponding DC level, albeit the pulse density modulated (PDM) equivalent thereof, wherein, for example, in one embodiment, the digital time series 332 from the sine shaper 328 is fed into an associated third mixer 376.3′ of the third demodulator 376.3 as an N-bit stream at the same over-sampled clock rate (e.g. 4 megahertz) as the signal from the second sigma-delta converter 358.2. The demodulated output from the third mixer 376.3′ is then filtered by a third low-pass filter 398.3, which is similar to the first 398.1 and second 398.2 low-pass filters described hereinabove.

The various signal conditioning circuits 294 in accordance with a first aspect illustrated in FIGS. 35-50 provide for determining the complex impedance of the coil 14, L′ by generating a measure responsive to the complex current i_(L) (i.e. in-phase (I) and quadrature-phase (Q) components thereof) therethrough responsive to a known or measured time-varying voltage V_(L) thereacross, particularly for an oscillatory, e.g. sinusoidal, voltage V_(L) thereacross.

Referring to FIG. 51, there is illustrated a combination of various embodiments that provide for various associated additional features that can be incorporated,—either singly, in combination, or in various subcombinations,—in any of the signal conditioning circuits 294 described hereinabove.

In accordance with a first feature, first 402.1 and second 402.2 LC filters are respectively placed in parallel with the first R_(S1) and second R_(S2) sense resistors, respectively, wherein the first LC filter 402.1 comprises a first inductor L₁ in parallel with a first capacitor C₁, and the second LC filter 402.2 comprises a second inductor L₂ in parallel with a second capacitor C₂, wherein, for example, the resonant frequencies of the first 402.1 and second 402.2 LC filters would be substantially equal to the operating frequency of the associated oscillator 98. Accordingly, at the normal operating frequency of the signal conditioning circuit 294, the impedances of the first 402.1 and second 402.2 LC filters would be relatively high so as to not substantially perturb the operation of the associated signal conditioning circuit 294, whereas at frequencies substantially different from the normal operating frequency of the signal conditioning circuit 294, the impedances of the first 402.1 and second 402.2 LC filters would be relatively low so as to substantially attenuate any associated voltages across the first R_(S1) and second R_(S2) sense resistors, thereby substantially attenuating a resulting associated voltage V_(out) from the summing and difference amplifier 276 representative of the current i_(L) through the coil 14, L′. Accordingly, the first 402.1 and second 402.2 LC filters provide for substantially attenuating the affects of electromagnetic interference (EMI) on the output of the signal conditioning circuit 294 at frequencies that are substantially different from the normal operating frequency thereof.

Referring to FIG. 52, the coil 14, L′ is typically connected to the signal conditioning circuit 294 with a cable 404, an equivalent circuit model 406 of which is illustrated in combination with an equivalent circuit model 408 of the coil 14, L′, wherein the first 402.1 and second 402.2 LC filters can be adapted in cooperation with the cable 404 and coil 14, L′ so as to provide for substantially maximizing the associated signal-to-noise ratio of the signal conditioning circuit 294 when operated in the presence of EMI.

Alternatively, the signal conditioning circuit 294 can be operated at a plurality of different frequencies, i.e. by operating the associated oscillator 30, 58, 98 at a plurality of different frequencies, for example, which are either sequentially generated, fore example, stepped or chirped, or simultaneously generated and mixed, wherein for at least three different frequency components, the associated processor 108, 204 can be adapted to provide for generating a corresponding associated spectrally dependent detected values, wherein an associated voting system can then be used to reject spectral component values that are substantially different from a majority of other spectral component values, for example, as a result of an electromagnetic interference (EMI) at the corresponding operating spectral frequency component(s) of the oscillator 30, 58, 98 of the spectral component that becomes rejected.

Referring again to FIG. 51, in accordance with a second feature, at least one of first 410.1 and second 410.2 comparators with hysteresis respectively provided to monitor the voltages across the first R_(S1) and second R_(S2) sense resistors respectively, provides for determining whether or not the current path containing the coil 14, L′ is open, wherein the first 410.1 and second 410.2 comparators with hysteresis respectively provide respective first 412.1 and second 412.2 signals that respectively indicate if the voltage across the respective first R_(S1) and second R_(S2) sense resistor is less than a threshold.

In accordance with a third feature, the sum-and-difference amplifier circuit 346 is adapted to provide for injecting a self-test signal V_(T) from a balanced signal source 414 therein so as to test the operation thereof, wherein the balanced signal source 414, controlled by associated switch elements 416, e.g. electronic switches, e.g. controlled by software, is injected through respective first RT1 and second RT2 resistors to the to non-inverting 280 and inverting 282 inputs, respectively, of the associated operational amplifier 278 of the sum-and-difference amplifier circuit 346, wherein, responsive to the injection of the predetermined self-test signal V_(T) through the associated switch element 416, if the resulting change in the voltage V_(out) from the sum-and-difference amplifier circuit 346 differs from a predetermined amount by more than a threshold, then an error signal would be generated indicative of a malfunction of the associated sum-and-difference amplifier circuit 346.

Referring to FIG. 53, in accordance with yet another embodiment, the inputs of each analog-to-digital converter 288 are provided with circuitry that provides for detecting whether the associated analog input signal is within acceptable limits. For example, the input 418 of a representative analog-to-digital converter 288, for example, a sigma-delta analog-to-digital converter 356, is connected to the non-inverting input 420.2 of a first comparator 422.1 and to the inverting input 424.1 of a second comparator 422.2. The inverting input 420.1 of the first comparator 422.1 is connected to a signal representative of a maximum threshold AC_(MAX), and the non-inverting input 424.2 of the second comparator 422.2 is connected to a signal representative of a minimum threshold AC_(MIN). The output 420.3 of the first comparator 422.1 is connected to a first input 426.1 of a two-input OR-gate 426, and the output 424.3 of the second comparator 422.2 is connected to a second input 426.2 of the OR-gate 426. The output 426.3 of the OR-gate 426 provides a signal 428 indicative of whether the input to the associated analog-to-digital converter 288 is either greater than the maximum threshold AC_(MAX) or less than the minimum threshold AC_(MIN), either of which would result if an associated peak-to-peak value was greater than an associated threshold. More particularly, if the level of the input 418 of the analog-to-digital converter 288 is greater than or equal to the maximum threshold AC_(MAX), then the output 420.3 of the first comparator 422.1 will be TRUE, causing the output 426.3 of the OR-gate 426 to be TRUE. If the level of the input 418 of the analog-to-digital converter 288 is less than or equal to the minimum threshold AC_(MIN), then the output 424.3 of the second comparator 422.2 will be TRUE, causing the output 426.3 of the OR-gate 426 to be TRUE. Otherwise the output 426.3 of the OR-gate 426 will be FALSE. The maximum threshold AC_(MAX) is set so that a level of the input 418 less than this level can be properly converted to digital form by the analog-to-digital converter 288. For example, for a sigma-delta analog-to-digital converter 356 illustrated in FIGS. 47-50, the maximum threshold AC_(MAX) would be set to a value less than or equal to one volt so as to provide for a digital output that is representative of the analog input. The minimum threshold AC_(MIN), if used, provides for detecting signals at the input 418 of the analog-to-digital converter 288 having a value less than the maximum threshold AC_(MAX) minus the maximum acceptable peak-to-peak level of the AC signal at the input 418 of the analog-to-digital converter 288. Accordingly, if the signal 428 at the output 426.3 of the OR-gate 426 is TRUE, then this would indicate that the resulting signal from the analog-to-digital converter 288 could be corrupted, for example, so as to alert the processor 108, 204 to ignore this signal.

Referring to FIG. 54, a twelfth embodiment of a signal conditioning circuit 294.12 that provides for generating one or more measures responsive to a self-impedance Z_(L) of a coil 14, L′, is substantially based upon the embodiment of the signal conditioning circuit 294 illustrated in FIG. 35, wherein like reference signs correspond to similar elements which function as described hereinabove, and FIG. 54 includes supplemental aspects as described hereinbelow. In some circumstances, external out-of-band electromagnetic interference can cause relatively large magnitude AC signal levels, relative to the in-band signal level, which otherwise are absorbed by the associated signal conditioning circuit 294. The twelfth embodiment of the signal conditioning circuit 294.12 is adapted with the third aspect of the bias control circuit 344.3 that utilizes feedback 345.3 so as to provide for controlling the respective voltages applied to the first 260 and fourth 272 nodes of the series circuit 242 so that they both relatively float with the out-of-band electromagnetic interference, thereby reducing the associated energy absorption requirements of the associated signal conditioning circuit 294. More particularly, this is accomplished by feeding the output, i.e. voltage V_(out), from the summing and difference amplifier 276 through a low-pass filter 430 and an all-pass phase shifter 432, and then using the resulting signal to control the coil driver 28, 56, 96. The cutoff frequency of the low-pass filter 430 is set substantially lower than the operating frequency of the oscillator 300, and sufficiently greater than zero, so as to provide for substantially cancelling the affect of the DC bias voltage sources 61 and 62 on the voltage V_(L) across the coil 14, L′, without substantially affecting, i.e. attenuating, the AC component thereof from the oscillator 300. The all-pass phase shifter 432 is adapted to exhibit a relatively flat gain response, and is adapted to provide sufficient phase margin so as to prevent the signal conditioning circuit 294.12 from oscillating as a result of the associated feedback connection.

Referring to FIG. 55, a thirteenth embodiment of a signal conditioning circuit 294.13 that provides for generating one or more measures responsive to a self-impedance Z_(L) of a coil 14, L′, is substantially based upon the tenth and twelfth embodiments of the signal conditioning circuits 294.10, 294.12 illustrated in FIGS. 45 and 54, wherein, except as noted otherwise, like reference signs correspond to similar elements which function as described hereinabove, and FIG. 55 includes supplemental aspects as described hereinbelow. In the thirteenth embodiment of a signal conditioning circuit 294.13, the summing and difference amplifier 276 is adapted to also function as the low-pass filter 430 by incorporating a feedback capacitor C_(F5) between the output of the associated operational amplifier 278 and the inverting input thereof. The output of the operational amplifier 278 is operatively coupled to a buffer amplifier 434 comprising a tenth operational amplifier 436, the output of which is then operatively coupled to the all-phase filter 432. The all-phase filter 432 comprises an eleventh operational amplifier 438, the non-inverting input of which is coupled through a capacitor C_(P1) to ground, and through a resistor R_(P1) to the output of the buffer amplifier 434, the latter of which is also operatively coupled through a resistor R_(P2) to the inverting input of the eleventh operational amplifier 438, which in turn is coupled through feedback resistor R_(P3) to the output of the eleventh operational amplifier 438. Several connections associated with the seventh 322 and eighth 326 operational amplifiers, and the oscillator 30, 58, 98 of the tenth embodiment of a signal conditioning circuit 294.10 are modified so as to provide for the thirteenth embodiment of a signal conditioning circuit 294.13. More particularly, the non-inverting inputs of the seventh 322 and eighth 326 operational amplifiers are each coupled directly to the first DC common mode voltage signal V_(CM1), rather than through the associated resistors R₉ and R₁₃. Furthermore, the output of the eighth operational amplifier 326 is coupled through the input resistor R₁₁ to the inverting input of the seventh operational amplifier 322, and the inverting input of the eighth operational amplifier 326 is operatively coupled through the second input resistor R₁₄ to the oscillator 30, 58, 98, and through the input resistor R₁₅ to the output of the eleventh operational amplifier 438, i.e. the output of the all-phase filter 432, wherein the oscillator 30, 58, 98 is biased by the first DC common mode voltage signal V_(CM1) applied to the non-inverting input of the eighth operational amplifier 326. Accordingly, the eighth operational amplifier 326 is configured as a summing amplifier 440, which provides for summing the biased output of the oscillator 30, 58, 98 with the output from the summing and difference amplifier 276 fed back through the low-pass filter 430 and the all-phase filter 432. The output signal V_(B) of the summing amplifier 440 is operatively coupled to the second operational amplifier 304 so as to provide for driving the fourth node 272 of the series circuit 242, and this output signal V_(B) is inverted by the seventh operational amplifier 322 so as to generate the complementary output signal V_(A) that is operatively coupled to the first operational amplifier 302 so as to provide for driving the first node 260 of the series circuit 242. Accordingly, the thirteenth embodiment of the signal conditioning circuit 294.13 incorporates the third aspect of a bias control circuit 344.3, using associated feedback 345.3 and incorporating a second aspect of control signals 347.2, that provides for adapting the output signals V_(A) and V_(B) responsive to the voltage V_(out) which is responsive to the current i_(L) through the series circuit 242, so as to substantially cancel DC and out-of-band signal components thereof for frequencies that are passed by the low-pass filter 430. Although the low-pass filter 430 is presently implemented in the summing and difference amplifier 276, it should be understood that this could also be implemented separately, for example, using the tenth operational amplifier 436 configured as a low-pass filter rather than as a buffer amplifier 434 as illustrated in FIG. 55.

Referring to FIG. 56, a fourteenth embodiment of a signal conditioning circuit 294.14 that provides for generating one or more measures responsive to a self-impedance Z_(L) of a coil 14, L′ incorporates the same structure as the twelfth embodiment of the signal conditioning circuit 294.12 illustrated in FIG. 54, except that the low-pass filter 430 of the twelfth embodiment is replaced with a notch filter 442 in the fourteenth embodiment. Referring to FIG. 57, the notch filter 442 exhibits a gain response G with a low frequency pass band 444 extending in frequency f up to a lower corner frequency f₁, a notch 446 centered about an associated center frequency f_(c), and a high frequency pass band 448 extending in frequency f from an upper corner frequency f₂, wherein the center frequency f_(c) is set substantially equal to the operating frequency of the oscillator 300. Accordingly, the fourteenth embodiment of the signal conditioning circuit 294.14 is adapted with a third aspect of a bias control circuit 344.3 that utilizes feedback 345.3 so as to provide for controlling the respective voltages applied to the first 260 and fourth 272 nodes of the series circuit 242 so that they both relatively float with the out-of-band electromagnetic interference in either the low 444 or high 448 frequency pass bands of the notch filter 442, thereby reducing the associated energy absorption requirements of the associated signal conditioning circuit 294, while nulling DC and low frequency current components having frequencies in the low frequency pass band 444 of the notch filter 442, and also nulling relatively high frequency current components having frequencies in the high frequency pass band 448 of the notch filter 442, while enabling the signal conditioning circuit 294.14 to control the voltage V_(L) across the coil 14, L′ and generate a voltage V_(out) responsive to the current i_(L) through the series circuit 242 at the operating frequency of the oscillator 300.

Examples of various notch filter 442 circuit embodiments are illustrated in FIGS. 58 a-c. Referring to FIG. 58 a, in accordance with a first embodiment of a notch filter 442.1, the input signal V_(IN) to be filtered is applied to a first terminal of a resistor R_(a) comprising a first arm of a two-arm bridge circuit 450. The second terminal of the resistor R_(a) is connected at a bridge junction 452 to both the second arm of the two-arm bridge circuit 450 and to the input of an inverting amplifier 454 which generates the associated filtered output signal V_(OUT), wherein the second arm of the two-arm bridge circuit 450 comprises a LC series network 455—comprising capacitor C_(a) and inductor L_(a)—connected to ground. At resonance of the LC series network 455, i.e. ω=1/√L_(a)C_(a), the impedance thereof is minimized resulting in the notch 446 of the notch filter 442.1.

Referring to FIG. 58 b, in accordance with a second embodiment of a notch filter 442.2, the input signal V_(IN) to be filtered is applied to an input resistor R_(b) which is coupled to the inverting input of an operational amplifier 456 that generates the associated filtered output signal V_(OUT), wherein the output of the operational amplifier 456 is operatively coupled through a bandpass feedback network 458 to the inverting input of the operational amplifier 456. The bandpass feedback network 458 comprises an inverting bandpass filter 460 in series with an inverting amplifier 462, wherein the inverting bandpass filter 460 comprises a series RC network 464—comprising resistor R_(1b) and capacitor C_(1b)—operatively coupled to the inverting input of an associated operational amplifier 466, and a parallel RC network 468—, comprising resistor R_(2b) and capacitor C_(2b)—operatively coupled between the inverting input and the output of the operational amplifier 466 so as to provide for feedback therethough. Accordingly, the inverting bandpass filter 460 is configured as a practical differentiator circuit as described in “An Applications Guide for Op Amps” by National Semiconductor, Application Note 20, February 1969, which is incorporated herein by reference. The associated center frequency f_(c) of the inverting bandpass filter 460 is given as follows by:

$\begin{matrix} {f_{c} = {\frac{1}{2\pi\; R_{1b}C_{1b}} = \frac{1}{2\pi\; R_{2b}C_{2b}}}} & (36) \end{matrix}$ and the lower corner frequency f₁ at a 20 dB gain reduction is given by:

$\begin{matrix} {f_{1} = \frac{1}{2\pi\; R_{2b}C_{1b}}} & (37) \end{matrix}$

Various other embodiments of notch filters 442 are known in the art, for example, as described by Adel S. Sedra and Kenneth C. Smith in Microelectronic Circuits, Third Edition, Oxford University Press, 1991, Section 11.6, pages 792-799 which is incorporated herein by reference. For example, referring to FIG. 58 c, a third embodiment of a notch filter 442.3, from FIG. 11.22( d) of the Sedra/Smith reference, incorporated herein by reference, comprises a first operational amplifier 470 configured as a buffer amplifier that receives the input signal V_(IN), an active filter network 471 comprising an output node 472, and a second operational amplifier 473 also configured as a buffer amplifier, the input of which is connected to the output node 472, the output of which provides the filtered output signal V_(OUT). The active filter network 471 comprises a first resistor R_(1c) between the output node 472 and the output of a third operational amplifier 474, a second resistor R_(2c) between the output and the inverting input of the third operational amplifier 474, a third resistor R_(3c) between the inverting input of the third operational amplifier 474 and an output of a fourth operational amplifier 475, a first capacitor C_(4c) between the output of the fourth operational amplifier 475 and the non-inverting input of the third operational amplifier 474, a fourth resistor R_(5c) between the non-inverting input of the third operational amplifier 474 and the output of the first operational amplifier 470, a fifth resistor R_(6c) between the output node 472 and ground, and a second capacitor C_(6c) between the output of the first operational amplifier 470 and the output node 472, wherein the non-inverting input of the fourth operational amplifier 475 is connected to the output node 472, and the inverting input of the fourth operational amplifier 475 is connected to the inverting input of the third operational amplifier 474. The transfer function of the third embodiment of the notch filter 442.3 is given as follows from Table 11.1 of the Sedra/Smith reference, incorporated herein by reference, as follows:

$\begin{matrix} {{T(s)} = \frac{K \cdot \left\lbrack {S^{2} + \frac{R_{2c}}{C_{4c} \cdot C_{6c} \cdot R_{1c} \cdot R_{3c} \cdot R_{5c}}} \right\rbrack}{S^{2} + \frac{S}{C_{6c} \cdot R_{6c}} + \frac{R_{2c}}{C_{4c} \cdot C_{6c} \cdot R_{1c} \cdot R_{3c} \cdot R_{5c}}}} & (38) \end{matrix}$

Referring to FIGS. 59, 61 and 63, the signal conditioning circuit 294 may be adapted to incorporate inner voltage feedback in combination with either current feedback or outer voltage feedback provided that the respective feedback control systems are adapted to not substantially interfere with one another.

For example, referring to FIG. 59, a fifteenth embodiment of a signal conditioning circuit 294.15 that provides for generating one or more measures responsive to a self-impedance Z_(L) of a coil 14, L′ incorporates a combination of an inner voltage feedback system 344.1—i.e. in accordance with the first aspect of the bias control circuit 344.1—of the tenth embodiment of the signal conditioning circuit 294.10 illustrated in FIG. 45, and a current feedback system 344.3—i.e. in accordance with the third aspect of the bias control circuit 344.3—of the thirteenth embodiment of the signal conditioning circuit 294.13 illustrated in FIG. 55, wherein a high-pass notch filter 476 is used instead of a low-pass filter 430 in the feedback path of the associated current feedback loop. More particularly, the output of the operational amplifier 278 of the summing and difference amplifier 276 is operatively coupled to a high-pass filter 478, for example, comprising a resistor R_(H) in series with a capacitor C_(H), the output of which is operatively coupled to a notch filter 442, for example, illustrated using the second embodiment of the notch filter 442.2 from FIG. 58 b, the output of which is operatively coupled to the buffer amplifier 434 and all-pass phase shifter 432 from the thirteenth embodiment of the signal conditioning circuit 294.13 illustrated in FIG. 55, so as to provide for the current feedback system 344.3. The associated single-ended complementary output signals V_(A) and V_(B) are generated by the associated oscillator 300 in accordance with the thirteenth embodiment of the signal conditioning circuit 294.13, and the inner voltage feedback system 344.1 is configured in accordance with the tenth embodiment of the signal conditioning circuit 294.10, both as described hereinabove.

Referring to FIG. 60, the cutoff frequency f_(L) of the low-pass filter circuit 312 of the inner voltage feedback system 344.1 is set sufficiently below the lower cutoff frequency f_(H) of the high-pass notch filter 476 of the current feedback system 344.3 so that the inner voltage feedback system 344.1 and the current feedback system 344.3 do not substantially interfere with one another. For example, in one embodiment, the separation 480 between the cutoff frequency f_(L) of the low-pass filter circuit 312 and the lower cutoff frequency f_(H) of the high-pass notch filter 476 is at least two decades.

Accordingly, for the fifteenth embodiment of the signal conditioning circuit 294.15 illustrated in FIG. 59, the inner voltage feedback system 344.1 provides for nulling DC and relatively lower frequency components of the current i_(L) through the coil 14, L′, the current feedback system 344.3 provides for nulling relatively higher frequency components of the current i_(L) through the coil 14, L′, and the notch 446 of the high-pass notch filter 476 provides for generating the one or more measures responsive to a self-impedance Z_(L) of the coil 14, L′ at the operating frequency of the associated oscillator 300, at which frequency neither the low-pass filter circuit 312 nor the high-pass notch filter 476 have a non-negligible affect on the current i_(L) through the coil 14, L′.

Referring to FIG. 61 a sixteenth embodiment of a signal conditioning circuit 294.16 that provides for generating one or more measures responsive to a self-impedance Z_(L) of the coil 14, L′ incorporates a combination of an inner voltage feedback system 344.1 and a current feedback system 344.3 similar to the fifteenth embodiment of the signal conditioning circuit 294.15 illustrated in FIG. 59 except that the high-pass notch filter 476 and the all-pass phase shifter 432 thereof are replaced a the second embodiment of a high-pass notch filter 476′ which incorporates the first embodiment of the notch filter 442.1 as illustrated in FIG. 58 a and described hereinabove, the input of which is operatively coupled to the output of the output of the operational amplifier 278 of the summing and difference amplifier 276, the output of which is operatively coupled to a high-pass filter 478, for example, comprising a resistor R₁₅ in series with a capacitor C_(H), the output of which is operatively coupled to the inverting input of the eighth operational amplifier 326 of the summing amplifier 440 of the oscillator 300, which provides the output signal V_(B) that is operatively coupled to the first operational amplifier 302 that drives the first node 260 of the series circuit 242, and which is input to the seventh operational amplifier 322 and inverted thereby so as to provide for the complementary output signal V_(A) that is operatively coupled to the second operational amplifier 304 that drives the fourth node 272 of the series circuit 242. Accordingly, for the sixteenth embodiment of the signal conditioning circuit 294.16 illustrated in FIG. 61, as with the fifteenth embodiment of the signal conditioning circuit 294.15 illustrated in FIG. 59, the inner voltage feedback system 344.1 provides for nulling DC and relatively lower frequency components of the current i_(L) through the coil 14, L′, the current feedback system 344.3 provides for nulling relatively higher frequency components of the current i_(L) through the coil 14, L′, and the notch 446 of the high-pass notch filter 476′ provides for generating the one or more measures responsive to a self-impedance Z_(L) of the coil 14, L′ at the operating frequency of the associated oscillator 300, at which frequency neither the low-pass filter circuit 312 nor the high-pass notch filter 476′ have a non-negligible affect on the current i_(L) through the coil 14, L′, wherein the low-pass filter circuit 312 and the high-pass notch filter 476′ are generally characterized by the gain responses G illustrated in FIG. 60.

Referring to FIG. 62, a seventeenth embodiment of a signal conditioning circuit 294.17 that provides for generating one or more measures responsive to a self-impedance Z_(L) of a coil 14, L′ incorporates the same structure as the eighth embodiment of the signal conditioning circuit 294.8 illustrated in FIG. 43, except that the low-pass filter circuit 312 of the eighth embodiment is replaced with a notch filter 442 in the seventeenth embodiment, wherein the notch filter 442 is implemented by a bandpass filter circuit 482 in the feedback path of the fifth operational amplifier 310, i.e. between the output and the non-inverting input thereof, wherein the notch filter 442 is generally characterized by the gain response G illustrated in FIG. 57 with the pass band of the bandpass filter circuit 482 defining the notch 446 of the notch filter 442. Accordingly, the seventeenth embodiment of the signal conditioning circuit 294.17 incorporates an outer voltage feedback system 344.2—i.e. in accordance with the first aspect of the bias control circuit 344.2—incorporating an associated notch filter 442, the low frequency pass band 444 of which that provides for nulling DC and relatively lower frequency components of the current i_(L) through the coil 14, L′, the high frequency pass band 448 of which provides for nulling relatively higher frequency components of the current i_(L) through the coil 14, L′, and the notch 446 of which provides for generating the one or more measures responsive to a self-impedance Z_(L) of the coil 14, L′ at the operating frequency of the associated oscillator 300.

Referring to FIG. 63, an eighteenth embodiment of a signal conditioning circuit 294.18 that provides for generating one or more measures responsive to a self-impedance Z_(L) of the coil 14, L′ incorporates a combination of an inner voltage feedback system 344.1—i.e. in accordance with the first aspect of the bias control circuit 344.1—of the tenth embodiment of the signal conditioning circuit 294.10 illustrated in FIG. 45, and an outer voltage feedback system 344.2, for example, generally in accordance with the seventeenth embodiment of a signal conditioning circuit 294.17 illustrated in FIG. 62, wherein a high-pass notch filter 476 is used instead of a notch filter 442 in the feedback path of the associated outer voltage feedback loop, and the feedback 345.2 of the outer voltage feedback system 344.2 is applied to the summing amplifier 440 associated with the oscillator 300 so as to directly affect both complementary output signals V_(A), V_(B) rather than to the non-inverting input of the second operational amplifier 304, which instead receives the feedback 345.1 of the inner voltage feedback system 344.1. More particularly, the first 260 and fourth 272 nodes of the of the series circuit 242 are respectively connected to first 482 and second 483 inputs of a differential amplifier 484, the output of which is operatively coupled to the high-pass notch filter 476, the output of which is operatively coupled through the input resistor R₁₅ to the inverting input of the eighth operational amplifier 326 configured as a summing amplifier 440 so as to provide for summing the feedback 345.2 of the outer voltage feedback system 344.2 into the output signal V_(B) that is applied to the fourth node 272 of the series circuit 242, and which is inverted to form the complementary output signal V_(A) that is applied to the first node 260 of the series circuit 242. Accordingly, the inner voltage feedback system 344.1 provides for nulling DC and relatively lower frequency components of the current i_(L) through the coil 14, L′, the outer voltage feedback system 344.2 provides for nulling relatively higher frequency components of the current i_(L) through the coil 14, L′, and the notch 446 of the high-pass notch filter 476 provides for generating the one or more measures responsive to a self-impedance Z_(L) of the coil 14, L′ at the operating frequency of the associated oscillator 300, at which frequency neither the low-pass filter circuit 312 nor the high-pass notch filter 476 have a non-negligible affect on the current i_(L) through the coil 14, L′.

It should be understood that any of the above embodiments incorporating a pair of sense resistors R_(S) may be adapted so that the associated current measure 348 that provides a measure of the current i_(L) through the coil 14, L′ is responsive only to the voltage across one of the two sense resistors R_(S), rather than to both, for example, by replacing the summing and difference amplifier 276 with a difference amplifier that generates a signal responsive to the voltage drop across one of the two sense resistors R_(S), or across a single sense resistors R_(S) of the associated series circuit 242.

Furthermore, referring to FIGS. 64-68, and further to the general embodiment illustrated in FIG. 36, a signal conditioning circuit 294 that provides for generating one or more measures responsive to a self-impedance Z_(L) of a coil 14, L′ may be adapted to do so using a single oscillatory drive signal as the source of voltage across the associated series circuit 242, rather than a pair of complementary output signals V_(A), V_(B), that otherwise provides for a balanced circuit and associated a reduced common mode voltage when used in combination with a pair of sense resistors R_(S). All of the embodiments illustrated in FIGS. 64-68 are adapted for single-supply operation of the associated amplifiers, e.g. operational amplifiers, i.e. using a mono-polar rather than a bi-polar power supply. Each of these embodiments incorporates a monopolar signal generator 600 comprising an oscillator 602 biased by a DC common mode voltage signal V_(CM1)—for example, having a value of about half the associated DC supply voltage—and operatively coupled through a first resistor R₁ to the inverting input of a first operational amplifier 604 configured as a summing amplifier. The output of the first operational amplifier 604 is operatively coupled through a second resistor R₂ to the inverting input of the first operational amplifier 604, and the DC common mode voltage signal V_(cm1) is operatively coupled to the non-inverting input of the first operational amplifier 604. Accordingly, if the oscillator 602 generates a sinusoidal voltage V_(AC), then if the values of the first R₁ and second R₂ resistors are equal to one another, the output V_(A) of the monopolar signal generator 600 is given by: V _(A) =V _(CM1) −V _(AC)  (39) which will be monopolar if the magnitude of the sinusoidal voltage V_(AC) is less than or equal to the magnitude of the DC common mode voltage signal V_(cm1).

The output V_(A) of the monopolar signal generator 600 is operatively coupled through a third resistor R₃ to the inverting input of a second operational amplifier 606, which is used as a driver 606′ to drive a series circuit 608 comprising the sense resistor R_(S) between a first node 260 and a second node 264, in series with the coil 14, L′ between the second node 264 and a third node 268, i.e. so as to apply a voltage across the series circuit 608 which causes a current i_(L) therethrough. More particularly, the output of the second operational amplifier 606 is operatively coupled to a first terminal of the sense resistor R_(S) at the first node 260 of the series circuit 608, and the second terminal of the sense resistor R_(S) at the second node 264 of the series circuit 608 is operatively coupled to a buffer amplifier 610′ comprising a third operational amplifier 610, the output of which is operatively coupled through a fourth resistor R₄ to the inverting input of the second operational amplifier 606. The non-inverting input of the second operational amplifier 606 is operatively coupled to the DC common mode voltage signal V_(CM1). Accordingly, the buffer amplifier 610′ applies the voltage V₂—of the second node 264 of the series circuit 608—to the fourth resistor R₄ which feeds back to the inverting input of the second operational amplifier 606, and which, for equal values of the third R₃ and fourth R₄ resistors, controls the voltage V₂ at the second node 264 of the series circuit 608 as follows: V ₂ =V _(CM1) +V _(AC)  (40)

The DC common mode voltage signal V_(cm1) is applied as voltage V₃ to the terminal of the coil 14, L′ at the third node 268 of the series circuit 608. Accordingly, the voltage V_(L) across the coil 14, L′, which is between the second 264 and third 268 nodes of the series circuit 608, is then given by: V _(L) =V ₂ −V ₃=(V _(CM1) +V _(AC))−V _(CM1) =V _(AC)  (41)

Accordingly, the driver 606′ configured with feedback through the buffer amplifier 610′ from the second node 264 of the series circuit 608 provides for controlling the voltage V_(L) across the coil 14, L′.

The first 260 and second 264 nodes of the series circuit 608—i.e. across the sense resistor R_(S)—are then operatively coupled to the inputs of a first differential amplifier 612, the output voltage V_(OUT) of which is responsive to the voltage drop V_(RS) across the sense resistor R_(S), which provides a measure of current through the coil 14, L′, and which is also biased by the DC common mode voltage signal V_(CM1) so as to provide for single-supply operation thereof.

Equation (41) shows that under ideal conditions, the voltage V_(L) across the coil 14, L′ does not exhibit a DC bias, so that under these conditions, there would be no corresponding DC current component through the coil 14, L′. However, as described hereinabove, a real operational amplifier can exhibit a DC bias, i.e. a non-zero output signal for no input signal, which can in turn cause a corresponding DC bias current in the series circuit 608 and coil 14, L′, which if not otherwise compensated, could possibly be problematic depending upon the magnitude thereof. Accordingly, the embodiments the signal conditioning circuits 294.19-294.23 of FIGS. 64-68 illustrate various inner voltage feedback systems 344.1, outer voltage feedback systems 344.2, and current feedback systems 344.3, alone and in combination with one another, that may be used to supplement the above-described circuitry so as to provide for mitigating the affects of biases and noise, if necessary for a particular application.

Referring to FIG. 64, a nineteenth embodiment of a signal conditioning circuit 294.19 that provides for generating one or more measures responsive to a self-impedance Z_(L) of a coil 14, L′ illustrates a general structure of an inner voltage feedback system 344.1 utilizing a single oscillatory drive signal as the source of voltage across the associated series circuit 242, which is a counterpart to the seventh and tenth embodiments of the signal conditioning circuits 294.7, 294.10 illustrated in FIGS. 42 and 45 respectively. More particularly, the inner voltage feedback system 344.1 comprises a second differential amplifier 614 and a low-pass filter 616, wherein the output of the buffer amplifier 610′ is operatively coupled to the inverting input of the second differential amplifier 614, the DC common mode voltage signal V_(CM1) (or the third node 268 of the series circuit 608) is operatively coupled to the non-inverting input of the second differential amplifier 614, and the output of the second differential amplifier 614 is operatively coupled to the low-pass filter 616, the output of which is operatively coupled through a fifth resistor R₅ to the inverting input of the first operational amplifier 604 in accordance with the second aspect of a control signal 347.2. Accordingly, the second aspect of the control signal 347.2 is given by the DC and low frequency components of (V₃−V₂), which, similar to the voltage V_(AC), is added to the voltage V_(L) across the coil 14, L′ in accordance with Equation (41) (if the values of the first R₁, second R₂ and fifth R₅ resistors are equal) so as to cancel the corresponding DC and low frequency components of (V₂−V₃) that generated the second aspect of the control signal 347.2 in the first place, so as to control the voltage V_(L) across the coil 14, L′ to be substantially equal to the voltage V_(AC).

Referring to FIG. 65, a twentieth embodiment of a signal conditioning circuit 294.20 that provides for generating one or more measures responsive to a self-impedance Z_(L) of a coil 14, L′ illustrates a general structure of an outer voltage feedback system 344.2 utilizing a single oscillatory drive signal as the source of voltage across the associated series circuit 242, which is a counterpart to the eighth and seventeenth embodiments of the signal conditioning circuits 294.8, 294.17 illustrated in FIGS. 43 and 62 respectively. More particularly, the outer voltage feedback system 344.2 comprises a second differential amplifier 614 and either a low-pass filter 616 or a notch filter 618, wherein the first node 260 of the series circuit 608 is operatively coupled to the inverting input of the second differential amplifier 614, the DC common mode voltage signal V_(CM1) (or the third node 268 of the series circuit 608) is operatively coupled to the non-inverting input of the second differential amplifier 614, and the output of the second differential amplifier 614 is operatively coupled to the low-pass filter 616, or to the notch filter 618, whichever is used, the output of which is operatively coupled through a fifth resistor R₅ to the inverting input of the first operational amplifier 604 in accordance with the second aspect of a control signal 347.2. Accordingly, the second aspect of a control signal 347.2 is given by either the DC and low frequency components of (V₃−V₁) in the case of a low-pass filter 616, or all but the notch 446 frequency components of (V₃−V₁) in the case of a notch filter 618, which provides for canceling the corresponding DC and other frequency components (depending upon whether a low-pass filter 616 or a notch filter 618 is used) of (V₁−V₃) that generated the second aspect of a control signal 347.2 in the first place, so as to control the voltage V_(L) across the coil 14, L′ to be substantially equal to the voltage V_(AC).

Referring to FIG. 66, a twenty-first embodiment of a signal conditioning circuit 294.21 that provides for generating one or more measures responsive to a self-impedance Z_(L) of a coil 14, L′ illustrates a general structure of a current feedback system 344.3 utilizing a single oscillatory drive signal as the source of voltage across the associated series circuit 242, which is a counterpart to the twelfth through fourteenth embodiments of the signal conditioning circuits 294.12-294.14 illustrated in FIGS. 54-56 respectively. More particularly, the current feedback system 344.3 comprises either a low-pass filter 616 or a notch filter 618, wherein the input polarities of the first differential amplifier 612 are reversed relative to the nineteenth and twentieth embodiments of the signal conditioning circuit 294.19, 294.20—i.e. with the inverting input thereof operatively coupled to the first node 260 of the series circuit 608, and the inverting input thereof operatively coupled to the output of the buffer amplifier 610′—so that the output voltage V_(OUT) thereof is responsive to (V₂−V₁=−V_(RS)), and the output of the first differential amplifier 612 is operatively coupled to the low-pass filter 616, or to the notch filter 618, whichever is used, the output of which is operatively coupled through a fifth resistor R₅ to the inverting input of the first operational amplifier 604 in accordance with the second aspect of a control signal 347.2. Accordingly, the second aspect of a control signal 347.2 is given by either the DC and low frequency components of (V₂−V₁) in the case of a low-pass filter 616, or all but the notch 446 frequency components of (V₂−V₁) in the case of a notch filter 618, which provides for canceling the corresponding DC and other frequency components (depending upon whether a low-pass filter 616 or a notch filter 618 is used) of (V₁−V₂) that generated the second aspect of the control signal 347.2 in the first place, so as to control the voltage V_(L) across the coil 14, L′ to be substantially equal to the voltage V_(AC).

Referring to FIG. 67, a twenty-second embodiment of a signal conditioning circuit 294.22 that provides for generating one or more measures responsive to a self-impedance Z_(L) of a coil 14, L′ illustrates a general structure of a combination of an inner voltage feedback system 344.1 with an outer voltage feedback system 344.2, both utilizing a single oscillatory drive signal as the source of voltage across the associated series circuit 242, which is a counterpart to the eighteenth embodiment of the signal conditioning circuits 294.18 illustrated in FIG. 63. More particularly, the inner voltage feedback system 344.1 is structured in accordance with the nineteenth embodiment of a signal conditioning circuit 294.19 illustrated in FIG. 64, as described hereinabove, and the outer voltage feedback system 344.2 comprises a third differential amplifier 620 and a high-pass notch filter 622, wherein the first node 260 of the series circuit 608 is operatively coupled to the inverting input of the third differential amplifier 620, the DC common mode voltage signal V_(CM1) (or the third node 268 of the series circuit 608) is operatively coupled to the non-inverting input of the third differential amplifier 620, and the output of the third differential amplifier 620 is operatively coupled to the high-pass notch filter 622, the output of which is operatively coupled through a sixth resistor R₆ to the inverting input of the first operational amplifier 604 in accordance with the second aspect of a control signal 347.2. The gain responses G of the low-pass filter 616 of the inner voltage feedback system 344.1 and the high-pass notch filter 622 of the outer voltage feedback system 344.2 are characterized in accordance with FIG. 60 as described hereinabove. Accordingly, the second aspect of a control signal 347.2 is given by the combination of the DC and low frequency components of (V₃−V₂) from the inner voltage feedback system 344.1, and the higher frequency excluding the notch 446 frequency components of (V₃−V₁), which provides for canceling the corresponding DC and other frequency components—except for at least the notch 446 frequency components—of (V₂−V₃) and (V₁−V₃) respectively, that collectively generated the second aspect of a control signal 347.2 in the first place, so as to control the voltage V_(L) across the coil 14, L′ to be substantially equal to the voltage V_(AC).

Referring to FIG. 68, a twenty-third embodiment of a signal conditioning circuit 294.23 that provides for generating one or more measures responsive to a self-impedance Z_(L) of a coil 14, L′ illustrates a general structure of a combination of an inner voltage feedback system 344.1 with a current feedback system 344.3, both utilizing a single oscillatory drive signal as the source of voltage across the associated series circuit 242, which is a counterpart to the fifteenth and sixteenth embodiments of the signal conditioning circuits 294.15, 294.16 illustrated in FIGS. 59 and 61 respectively. More particularly, the inner voltage feedback system 344.1 is structured in accordance with the nineteenth embodiment of a signal conditioning circuit 294.19 illustrated in FIG. 64, as described hereinabove, and the current feedback system 344.3 comprises a high-pass notch filter 622, wherein the input polarities of the first differential amplifier 612 are configured as in the twenty-first embodiment of a signal conditioning circuit 294.21—i.e. with the inverting input thereof operatively coupled to the first node 260 of the series circuit 608, and the inverting input thereof operatively coupled to the output of the buffer amplifier 610′—so that the output voltage V_(OUT) thereof is responsive to (V₂−V₁=−V_(RS)), and the output of the first differential amplifier 612 is operatively coupled to the high-pass notch filter 622, the output of which is operatively coupled through a sixth resistor R₆ to the inverting input of the first operational amplifier 604 in accordance with the second aspect of a control signal 347.2. The gain responses of the low-pass filter 616 of the inner voltage feedback system 344.1 and the high-pass notch filter 622 of the current feedback system 344.3 are characterized in accordance with FIG. 60 as described hereinabove. Accordingly, the second aspect of a control signal 347.2 is given by the combination of the DC and low frequency components of (V₃−V₂) from the inner voltage feedback system 344.1, and the higher frequency excluding the notch 446 frequency components of (V₂−V₁), which provides for canceling the corresponding DC and other frequency components—except for at least the notch 446 frequency components—of (V₂−V₃) and (V₁−V₂), respectively, that collectively generated the second aspect of a control signal 347.2 in the first place, so as to control the voltage V_(L) across the coil 14, L′ to be substantially equal to the voltage V_(AC).

Referring to FIGS. 69 a-c, 70 a-c, 71 a-b, 72, and 73 a-e, a second aspect of a signal conditioning circuit 502 provides for generating a measure responsive to the complex impedance of the coil 14, L′ using a time constant method, wherein the time constant of an associate RL or RLC circuit incorporating the coil determines the time response thereof to a pulse applied thereto, and a measure responsive to the complex impedance of the coil 14, L′ responsive to one or more measures of this time response.

Referring to FIG. 69 a, in accordance with a first embodiment of the second aspect of the signal conditioning circuit 502.1 that provides for generating one or more measures responsive to a self-impedance Z_(L) of a coil 14, L′, a monopolar pulse generator 504 under control of a processor 108, 204 is operatively coupled across a series combination of a sense resistor R_(sense) and the coil 14, L′, in parallel with a series combination of a second resistor R₂ and a diode D that is reverse biased relative to the polarity of the monopolar pulse generator 504. Referring to FIGS. 70 a-c, examples of various embodiments of the monopolar pulse generator 504 include a battery 506 in series with a controlled switch 508, e.g. a transistor or relay, as illustrated in FIG. 70 a; a battery 506 in series with an FET transistor switch 508′, as illustrated in FIG. 70 b; and an oscillator circuit that provides for the generation of a monopolar pulse train 510 as illustrated in FIG. 70 c. A differential amplifier 512 generates a signal V_(OUT) responsive to the voltage V_(sense) across the sense resistor R_(sense), which is responsive to the current i_(L) through the coil 14, L′ in accordance with Ohm's law, i.e. V_(sense)=R_(sense)·i_(L). Referring to FIG. 69 b, the coil 14, L′ can be modeled as an inductor L in series with a resistor R_(L), wherein the resistance R_(L) accounts for the combination of the inherent resistance of the coil 14, L′ and the effective resistance resulting from proximal eddy current effects. The monopolar pulse generator 504 generates a pulse 514, e.g. upon closure of the controlled switch 508 or the FET transistor switch 508′, and, referring to FIG. 69 c, the subsequent rate of increase of the current i_(L) provides a measure of the inductance L and resistance R_(L), which together provide the impedance Z of the coil 14, L′. The time constant τ_(ON) of a pure R_(L) circuit would be given by:

$\begin{matrix} {\tau_{ON} = \frac{R_{{sense}\;} + R_{L}}{L}} & (42) \end{matrix}$ and the current i_(L) would be given as follows:

$\begin{matrix} {{i_{L}(t)} = {\frac{V}{R_{sense} + R_{L}} \cdot \left( {1 - {\mathbb{e}}^{- \frac{{({R_{sense} + R_{L}})} \cdot t}{L}}} \right)}} & (43) \end{matrix}$

If the duration of the pulse 514 were sufficiently long, e.g. t>>, the current i_(L) would approach a value of:

$\begin{matrix} {i_{L}^{\max} = \frac{V}{R_{sense} + R_{L}}} & (44) \end{matrix}$

The pulse 514 is held on for a duration sufficient to provide for measuring the time constant τ_(ON), for example, responsive to any of the following: 1) the current i_(L) at and associated time t as the current i_(L) is rising, e.g. at the end of a pulse 514 having a duration less than several time constants τ_(ON); 2) the rate of change of current i_(L) as the current i_(L) is rising; 3) the time or times required after initiation of a pulse 514 for the current i_(L) to reach a predetermined value or to reach a set of predetermined values; or 4) an integral of the current i_(L) over at least a portion of the period when the pulse 514 is on.

For example, from Equation (43) may be rewritten as:

$\begin{matrix} {{i_{L}(t)} = {i_{L}^{\max} \cdot \left( {1 - {\mathbb{e}}^{- \frac{t}{\tau}}} \right)}} & (45) \end{matrix}$ where τ=τ_(ON). The first derivative of the current i_(L) with respect to time is given by:

$\begin{matrix} {{i_{L}^{\prime}(t)} = {i_{L}^{\max} - {\frac{\tau}{t} \cdot {\mathbb{e}}^{- \frac{i}{\tau}}}}} & (46) \end{matrix}$ From Equations (45) and (46), the current i_(L) can be given as a function of the first derivative of the current i_(L) as:

$\begin{matrix} {{i_{L}(t)} = {i_{L}^{\max} - {\frac{\tau}{t} \cdot {i_{L}^{\prime}(t)}}}} & (47) \end{matrix}$ If the current i_(L) is measured as is and i₂ at two corresponding different times t₁ and t₂, and if the first derivative of the current i_(L) is determined as i₁′ and i₂′ at these same times, then the time constant τ_(ON) is given by:

$\begin{matrix} {\tau_{ON} = {\frac{i_{2} - i_{1}}{\left( {\frac{i_{1}^{\prime}}{t_{1}} - \frac{i_{2}^{\prime}}{t_{2}}} \right)} = \frac{L}{R_{sense} + R_{L}}}} & (48) \end{matrix}$ From Equations (47) and (44), the effective resistance R_(L) of the coil 14, L′ is then given by:

$\begin{matrix} {R_{L} = {{\frac{V}{i_{1} + {\frac{\tau_{ON}}{t_{1}} \cdot i_{1}^{\prime}}} - R_{sense}} = {\frac{V}{i_{2} + {\frac{\tau_{ON}}{t_{2}} \cdot i_{2}^{\prime}}} - R_{sense}}}} & (49) \end{matrix}$ and the inductance L of the coil 14, L′ is given by: L=τ _(ON)·(R _(sense) +R _(L))  (50)

After the pulse 514 is turned off, e.g. upon the opening of the controlled switch 508 or the FET transistor switch 508′, the energy stored in the coil 14, L′ is dissipated relatively quickly through the parallel circuit path of the second resistor R₂ in series with the diode D, having a time constant τ_(OFF) given by:

$\begin{matrix} {\tau_{OFF} = \frac{R_{sense} + R_{L} + R_{2}}{L}} & (51) \end{matrix}$ wherein the value of the second resistor R₂ is chosen to magnetically discharge the coil 14, L′ to zero current i_(L) before the next pulse 514. A monopolar pulse train 510 as illustrated in FIG. 70 c can be used to make a continuous plurality of measurements, which can be averaged—over a selectable number of pulses 514, on a fixed or running basis—or used individually, depending upon the rate at which the resulting measure(s) is/are to be updated. Equation (43) and the associated measurement process can also be adapted to account for the affect of the inherent capacitance of the coil 14, L′, if non-negligible.

Referring to FIG. 71, a second embodiment of the second aspect of a signal conditioning circuit 502.2 is similar to the first embodiment of signal conditioning circuit 502.1 described hereinabove except that the monopolar pulse generator 504 is replaced with a bipolar pulse generator 516, and the diode D is replaced with a transistor switch 518, e.g. an FET switch 518′, wherein, the bipolar pulse generator 516 is adapted to generate a bipolar pulse train 520, one embodiment of which, for example, is illustrated in FIG. 72. The second aspect of a signal conditioning circuit 502.2 provides for periodically reversing the direction of current i_(L) through the coil 14, L′ so as to prevent a magnetization of associated ferromagnetic elements, e.g. of the vehicle 12, in proximity thereto. The bipolar pulse train 520 comprises both positive 514 and negative 514′ polarity pulses, during which times the transistor switch 518 would be switched off to provide for magnetically charging the coil 14, L′; separated by dwell periods 522 of zero voltage, during which times the transistor switch 518 would be switched on to provide for magnetically discharging the coil 14, L′.

Referring to FIG. 73, a third embodiment of the second aspect of a signal conditioning circuit 502.3 is similar to the first embodiment of signal conditioning circuit 502.1 described hereinabove—incorporating the embodiment of the monopolar pulse generator 504 illustrated in FIG. 70 b—except that the coil 14, L′ is driven through an H-switch 524 so as to provide for periodically reversing the direction of current i_(L) through the coil 14, L′ so as to prevent a magnetization of associated ferromagnetic elements, e.g. of the vehicle 12, in proximity thereto, without requiring a bipolar pulse generator 516 and associated bipolar electronic elements. The H-switch 524 comprises respective first 526 and second 528 nodes, respectively connected to the sense resistor R_(sense) and monopolar pulse generator 504 respectively, as had been connected the coil 14, L′ in the first embodiment of the second aspect of a signal conditioning circuit 502.1. The H-switch 524 also comprises respective third 530 and fourth 532 nodes respectively connected to the first 534 and second 536 terminals of the coil 14, L′. A first transistor switch 538 (e.g. FET switch) under control of a first switch signal S_(A) from the processor 108, 204 is operative to control a flow of current between the first 526 and third 530 nodes of the H-switch 524. A second transistor switch 540 (e.g. FET switch) under control of a second switch signal S_(B) from the processor 108, 204 is operative to control a flow of current between the first 526 and fourth 532 nodes of the H-switch 524. A third transistor switch 542 (e.g. FET switch) under control of the second switch signal S_(B) from the processor 108, 204 is operative to control a flow of current between the second 528 and third 530 nodes of the H-switch 524. A fourth transistor switch 544 (e.g. FET switch) under control of the first switch signal S_(A) from the processor 108, 204 is operative to control a flow of current between the second 528 and fourth 532 nodes of the H-switch 524. The FET transistor switch 508′ of the monopolar pulse generator 504 under control of pulse switch signal S₀ controls the flow of current from the battery 506 to the coil 14, L′.

Referring to FIGS. 74 a-e, the signal conditioning circuit 502.3 is controlled as follows: In a first step 546, the pulse switch signal S₀ and the first switch signal S_(A) are activated, which turns the FET transistor switch 508′ and the first 538 and fourth 544 transistor switches on, thereby providing for current i_(L) to flow through the coil 14, L′ in a first direction. Then, in a second step 548, the pulse switch signal S₀ is deactivated without changing the first switch signal S_(A), thereby providing for the coil 14, L′ to magnetically discharge through the second resistor R and diode D, with current i_(L) continuing to flow through the coil 14, L′ in the first direction until dissipated. Then, in a third step 550, first switch signal S_(A) is deactivated which turns the first 538 and fourth 544 transistor switches off, after which the pulse switch signal S₀ and the second switch signal S_(B) are activated, which turns the FET transistor switch 508′ and the second 540 and third 542 transistor switches on, thereby providing for current i_(L) to flow through the coil 14, L′ in a second direction. Finally, in a fourth step 552, the pulse switch signal S₀ is deactivated without changing the second switch signal S_(B), thereby providing for the coil 14, L′ to magnetically discharge through the second resistor R and diode D, with current i_(L) continuing to flow through the coil 14, L′ in the second direction until dissipated. After the fourth step 552, the above process repeats with the first step 546 as described hereinabove.

Referring to FIG. 75 a, in accordance with a third aspect of a signal conditioning circuit 554 that provides for generating one or more measures responsive to a self-impedance Z_(L) of a coil 14, L′ from a measurement of a differential voltage V_(out) of a four-arm bridge circuit 556 incorporating the as one of the arms 558. More particularly, for example, in one embodiment of the four-arm bridge circuit 556, the first 558.1 and second 558.2 arms respectively comprise first R_(B) and second R_(B) bridge resistors, e.g. for example, of equal value, which are interconnected at a first node 560 of the four-arm bridge circuit 556. The third arm 558.3 comprises the coil 14, L′ and the associated cabling, wherein the coil 14, L′ is modeled as an inductor L in series with a resistor R_(L), and the associated cabling and inter-coil capacitance of the coil 14, L′ is modeled as a first capacitor C₁ in parallel with the coil 14, L′. The fourth arm 358.4 comprises a gyrator 562 in parallel with a second capacitor C₂. The third 558.3 and fourth 358.4 arms are interconnected at a second node 564 of the four-arm bridge circuit 556. An oscillator 566 and associated amplifier 568 are interconnected across the first 560 and second 564 nodes, and provide for generating an oscillatory signal, e.g. a sinusoidal signal, thereacross. The second 558.2 and fourth 558.4 arms of the four-arm bridge circuit 556 are interconnected at a third node 570 which is connected to a first input 572 of a differential amplifier 574; and the first 558.1 and third 558.3 arms of the four-arm bridge circuit 556 are interconnected at a fourth node 576 which is connected to a second input 578 of the differential amplifier 574. Accordingly, the two bridge resistors R_(B) provide for balancing the second 558.2 and fourth 558.4 arms of the four-arm bridge circuit 556, and the combination of the gyrator 562 in parallel with the second capacitor C₂ in the fourth arm 558.4 provides for balancing the coil 14, L′ in the third arm 558.3, thereby providing for balancing the four-arm bridge circuit 556 so as to null the associated differential voltage V_(out) thereof, which is given by the difference between the voltage V₁ at the third node 570 and the voltage V₂ at the fourth node 576. The gyrator 562 is an active circuit two terminal circuit using resistive and capacitive elements, which provides for modeling an inductor of arbitrary inductance and series resistance. More particularly, a first gyrator resistor R_(L)′ is connected from a first terminal 580 of the gyrator 562 to the inverting input of an operational amplifier 582, which is also connected by a feedback loop 584 to the output 586 of the operational amplifier 582. A gyrator capacitor C_(G) is connected from the first terminal 580 of the gyrator 562 to the non-inverting input of the operational amplifier 582, which is also connected to a second gyrator resistor R_(G), which is then connected to the second terminal 588 of the gyrator 562. Referring to FIG. 75 b, the equivalent circuit of the gyrator 562 illustrated in FIG. 75 a comprises a resistor R_(L)′ having a resistance R_(L)′ equal to that of the first gyrator resistor R_(L)′, in series with an inductor L_(G) having an inductance L_(G) given as follows: L _(G) =R′ _(L) ·R _(G) ·C _(G)  (52)

In one embodiment, for example, the resistance R_(G) of second gyrator resistor R_(G) is controlled to control the effective inductance L_(G) of the gyrator 562 so as to balance or nearly balance the four-arm bridge circuit 556, i.e. so that the differential voltage V_(out) is nulled or nearly nulled. The second capacitor C₂ is provided to balance the first capacitor C₁, wherein, for example, in one embodiment, the value of the second capacitor C₂ is set equal to or slightly greater than the value of the first capacitor C₁, but would not be required if the associated capacitances of the cabling and coil 14, L′ were negligible. The resistance of the first gyrator resistor R_(L)′ is provided to balance the combination of the inherent resistance of the coil 14, L′, the resistance of the associated cabling, and the effective resistance of proximal eddy currents upon the coil 14, L′. One or both of the first R_(L)′ and second R_(G) gyrator resistors can be made controllable, e.g. digitally controllable, and the value of the gyrator capacitor C_(G) would be chosen so as to provide for a necessary range of control of the inductance L_(G) of the gyrator 562 to match that of the coil 14, L′, given the associated control ranges of the first R_(L)′ and second R_(G) gyrator resistors. For example, the values of the first R_(L)′ and second R_(G) gyrator resistors can be slowly updated by an associated processor 108, 204 so as to maintain a desired level of balance of the four-arm bridge circuit 556 during normal, non-crash operating conditions. When the four-arm bridge circuit 556 is nulled, i.e. so as to null the differential voltage V_(out), then the values of the resistance R_(L) and inductance L of the coil 14, L′ are given as follows:

$\begin{matrix} {{R_{L} = {R_{L}^{\prime} \cdot \frac{R_{A}}{R_{B}}}},\mspace{14mu}{and}} & (53) \\ {L = {L_{G} \cdot \frac{R_{A}}{R_{B}}}} & (54) \end{matrix}$

In another embodiment, the inductance L_(G) of the gyrator 562 is adapted to be slightly lower than the inductance of the coil 14, L′ so that the differential voltage V_(out) is not completely nulled, so as to provide a continuous small signal during normal operation, which allows for real-time diagnostics of the coil 14, L′ and associated signals and circuitry. Under off-null conditions, the output of the differential amplifier 574 would generally be complex or phasor valued, which would be demodulated, for example into in-phase (I) and quadrature-phase (Q) components,—for example, using circuitry and processes described hereinabove for FIGS. 46-50,—for subsequent processing and/or associated crash detection.

The third aspect of a signal conditioning circuit 554 can be adapted to provide relatively high accuracy measurements, with relatively high resolution, of the self-impedance Z_(L) of a coil 14, L′.

In either mode of operation, i.e. nulled or off-null, and generally for any of the aspects of the signal conditioning circuits described herein, the associated signal detection process may be implemented by simply comparing the output of the signal conditioning circuit with an associated reference value or reference values, wherein the detection of a particular change in a magnetic condition affecting the coil 14 is then responsive to the change in the associated signal or signals relative to the associated value or reference values. Accordingly, whereas the in-phase (I) and quadrature (Q) phase components of the signal can be determined analytically and related to the associated impedance Z of the coil 14, this is not necessarily necessary for purposes of detecting a change in an associated magnetic condition affecting the coil 14, which instead can be related directly to changes in the associated signals from the signal conditioning circuit.

Referring to FIG. 76 a, in accordance with a fourth aspect of a signal conditioning circuit 590 that provides for generating one or more measures responsive to a self-impedance Z_(L) of a coil 14, L′, a multi-frequency signal 592 is generated by summing and amplifying a plurality of signals from an associated plurality of oscillators 594.1, 594.2, 594.3 operating a corresponding plurality of different frequencies f₁, f₂, f₃ are applied to the coil 14, L′ in series with a sense resistor R_(sense), wherein the operations of summing and amplifying may be performed by a operational amplifier 596 adapted as a summing amplifier 598. The self-impedance Z_(L) of the coil 14, L′ at a frequency f is given by: Z _(L) =R _(L)+2πf·L  (55) wherein R_(L) and L are the effective resistance and the self-inductance of the coil 14, L′, respectively. Accordingly, for a frequency-dependent applied voltage signal v(f) from the summing amplifier 598, the complex voltage V_(sense) across the sense resistor R_(sense) is given by:

$\begin{matrix} {V_{Sense} = {\frac{v(f)}{\left( {1 + \frac{R_{L}}{R_{Sense}}} \right) \cdot \left( {1 + \frac{f^{2}}{f_{0}^{2}}} \right)} \cdot \left( {1 - {{\mathbb{i}} \cdot \frac{f}{f_{0}}}} \right)}} & (56) \end{matrix}$ wherein the cut-off frequency f₀ of the associated low-pass filter comprising the coil 14, L′ in series with the sense resistor R_(sense) is given by:

$\begin{matrix} {f_{0} = \frac{R_{Sense} + R_{L}}{2{\pi \cdot L}}} & (57) \end{matrix}$

The frequency-dependent current i_(L) through the coil 14, L′ is then given by:

$\begin{matrix} {{i_{L} = {\frac{V_{Sense}}{R_{Sense}} = \frac{v(f)}{R_{Sense} \cdot \left( {1 + \frac{R_{L}}{R_{Sense}}} \right) \cdot \left( {1 + \frac{f^{2}}{f_{0}^{2}}} \right)}}}{\cdot \left( {{1 - i}{\cdot \frac{f}{f_{0}}}} \right)}} & (58) \end{matrix}$ having a corresponding frequency dependent magnitude ∥i_(L)∥ and phase φ respectively given by:

$\begin{matrix} {{{i_{L}} = \frac{v(f)}{{R_{Sense} \cdot \left( {1 + \frac{R_{L}}{R_{Sense}}} \right)}{\cdot \left( {1 + \frac{f^{2}}{f_{0}^{2}}} \right)^{\frac{1}{2}}}}},{and}} & (59) \\ {\phi = {\tan^{- 1}\left( {- \frac{f}{f_{0}}} \right)}} & (60) \end{matrix}$

The voltage V_(L) across the coil 14, L′ is given by: V _(L)=v(f)−V _(Sense)  (61) which provides a phase reference and therefore has a phase of 0 degrees. The ratio of the voltage V_(L) across the coil 14, L′ to the current i_(L) through the coil 14, L′ provides a measure of the self-impedance Z_(L) of a coil 14, L′. The voltage V_(sense) is sensed with a differential amplifier 599, the output of which is operatively coupled to a processor 108, 204 for subsequent analysis.

Referring to FIG. 76 b, the magnitude ∥i_(L)∥ and phase φ of the current i_(L) through the coil 14, L′ is dependent upon the frequency of the applied voltage signal v(f), and will be different for each of the different associated frequency components associated with the plurality of different frequencies f₁, f₂, f₃. Although a single frequency f can be used, plural frequencies f₁, f₂, f₃ provide additional information that provides some immunity to the affects of noise and electromagnetic interference on the associated measurements. For example, if the frequency-dependent ratio of the voltage V_(sense) across the sense resistor R_(sense) to the applied voltage signal v(f) is inconsistent with that which would be expected from Equation (56) for one or more frequencies f₁, f₂, f₃, then the measurements at those frequencies may be corrupted. Three or more frequencies f₁, f₂, f₃ distributed over a frequency range can provide for determining if any of the associated measurements are affected by a particular noise source.

Although the signal conditioning circuits 294 described herein have been illustrated for generating a measure responsive to a self-impedance of a coil, in general, these signal conditioning circuits 294 may generally be used to measure the impedance of a two terminal circuit element, or a two terminal combination of circuit elements so as to provide for generating a measure responsive to the self-impedance of the two terminal circuit element or the two terminal a combination of circuit elements.

Referring to FIGS. 77 and 78, in accordance with a fifth aspect of a signal conditioning circuit 700 that provides for generating one or more measures responsive to a self-impedance Z_(L) of a coil 14, L′, a series circuit 702 incorporating the coil 14, L′ in series with a sense resistor R_(S) is driven by a half-sine signal 704 through an associated H-switch 706 that provides for controlling the polarity of the half-sine signal 704 relative to the series circuit 702. The half-sine signal 704 is generated by a half-sine generator 708, which in one embodiment, digitally generates the half-sine signal 704 using a table-lookup of a quarter-sine waveform 710 and associated software control logic, and also generates a polarity control signal p for controlling the H-switch 706. The digital output of the half-sine generator 708 is converted to the analog half-sine signal 704 using a digital-to-analog converter 712, the output of which can be subsequently filtered to remove noise. The H-switch 706 comprises a first switch 706.1 operative between a first node 714.1 and a second node 714.2, a second switch 706.2 operative between the second node 714.2 and a third node 714.3, a third switch 706.3 operative between the second node 714.2 and a fourth node 714.4, and a fourth switch 706.4 operative between the fourth node 714.4 and the first node 714.1, wherein the half-sine signal 704 is applied to the first node 714.1, the third node 714.3 is connected to ground, and the series circuit 702 is connected between the second 714.2 and fourth 714.4 nodes. For example, in one embodiment, the first 706,1, second 706.2, third 706.3, and fourth 706.4 switches of the H-switch 706 comprise transistor switches, for example, field-effect transistor switches as illustrated in FIG. 77. The control terminals, e.g. gates, of the first 706.1 and third 706.3 switches are operatively coupled to the polarity control signal p, which is also operatively coupled to an inverter 716 that generates an inverse polarity control signal p′, which is operatively coupled to the control terminals, e.g. gates, of the second 706.2 and fourth 706.4 switches. The activity of the polarity control signal p and the inverse polarity control signal p′ is mutually exclusive, i.e. when the polarity control signal p is in an ON state, so as to turn the first 706.1 and third 706.3 switches on, the inverse polarity control signal p′ is in an OFF state, so as to turn the second 706.2 and fourth 706.4 switches off, and when the polarity control signal p is in an OFF state, so as to turn the first 706.1 and third 706.3 switches off, the inverse polarity control signal p′ is in an ON state, so as to turn the second 706.2 and fourth 706.4 switches on. Accordingly, for a positive half-sine signal 704, when the polarity control signal p is in the ON state, the H-switch 706 applies the half-sine signal 704 to the series circuit 702 such that current i_(L) flows therethrough from the second node 714.2 to the fourth node 714.4, and when the polarity control signal p is in the OFF state, the H-switch 706 applies the half-sine signal 704 to the series circuit 702 such that current i_(L) flows therethrough from the fourth node 714.4 to the second node 714.2. The polarity control signal p and the inverse polarity control signal p′ are synchronized with the half-sine signal 704 so that the states thereof are switched after the completion of each half-sine waveform of the half-sine signal 704, the latter of which comprises a continuous repetition of half-sine waveforms.

Referring to FIG. 78, a process 7800 for generating the half-sine signal 704 and the polarity control signal p commences with step (7802), wherein a first counter k, a second counter m, and the polarity control signal p are each initialized to zero. Then, in step (7804), the a table-lookup is performed using the value of the first counter k to look up the k^(th) value of the corresponding quarter-sine waveform 710 from a table of NSIN4 values, which in step (7806) is output to the digital-to-analog converter 712 as the value of the half-sine signal 704. Then, in step (7808), if the value of the second counter m, which is associated with the increasing portion of the associated half-sine waveform, then in step (7810), the value of the first counter k is incremented by one; otherwise, in step (7812), the value of the first counter k is decremented by one. Then, in step (7814), if the value of the first counter k is greater than or equal to NSIN4, the number of values in the quarter-sine table, then, in step (7816), the second counter m is set to a value of one, and, in step (7818), the first counter k is set to a value of NSIN4-2, so as to prepare for generating the decreasing portion of the associated half-sine waveform. Otherwise, from step (7814), if, in step (7820), the value of the first counter k is less than zero, then the half-sine waveform has been competed and, in step (7822), the value of the first counter k is set to one, the value of the second counter m is set to zero, and the value of the polarity control signal p is incremented by one, and then set to the modula-2 value of the result, so as to effectively toggle the polarity control signal p, and so as to prepare for generating the increasing portion of the next half-sine waveform. Then, following any of steps 7818, 7820 or 7822, the process continues with step 7804, so as to repetitively generate the associated half-sine waveform, which provides for the half-sine signal 704.

Accordingly, the half-sine signal 704 in cooperation with the control of the associated H-switch 706 by the polarity control signal p provides for generating the equivalent of a zero-biased sine waveform across the series circuit 702, the current i_(L) through which is detected by the sum and difference amplifier 718 comprising an operational amplifier 720, the inverting input of which is connected through a first resistor 722 to one terminal of the sense resistor R_(S), designated by voltage V₁, the non-inverting input of which is connected through a second resistor 724 to the other terminal of the sense resistor R_(S), designated by voltage V₂, and through a third resistor 726 to the DC common mode voltage signal V_(CM1), and the output of which is connected through a fourth resistor 728 to the non-inverting input thereof, and which provides the voltage V_(OUT) representative of the current i_(L) through the coil 14, L′, as follows: V _(OUT) V ₂ −V ₁ +V _(CM1) =i _(L) ·R _(S) +V _(CM1)  (62)

Referring to FIGS. 79 and 80, the affect of electromagnetic noise on a first magnetic crash sensor 10 ^(A) may be mitigated through cooperation with a second magnetic crash sensor 10 ^(B), both located so to be responsive to substantially the same electromagnetic noise. For example, in the embodiment illustrated in FIG. 79, the first magnetic crash sensor 10 ^(A) comprises a first coil 14 ^(A) located in a first door 78 ^(A) of a vehicle 12, and the second magnetic crash sensor 10 ^(B) comprises a second coil 14 ^(B) located in a second door 78 ^(B) of the vehicle 12, wherein the first 78 ^(A) and second 78 ^(B) doors are opposing one another so that the first 14 ^(A) and second 14B coils experience substantially the same external magnetic noise flux that might extend transversely through the vehicle 12. The first magnetic crash sensor 10 ^(A) further comprises a first signal conditioning circuit 294 ^(A), for example in accordance with any of the embodiments disclosed herein, operatively coupled to the first coil 14 ^(A). Similarly, the second magnetic crash sensor 10 ^(B) further comprises a second signal conditioning circuit 294 ^(B), for example in accordance with any of the embodiments disclosed herein, operatively coupled to the second coil 14B. The outputs of the first 294 ^(A) and second 294 ^(B) signal conditioning circuits of are operatively coupled to an associated processor 108, 204, which provides for controlling respective first (44,110)^(A) and second (44,110)^(B) safety restraint actuators associated with the first 78 ^(A) and second 78 ^(B) doors, respectively.

Referring to FIG. 80, the processor 108, 204 operates in accordance with a noise rejection process 8000 that provides for mitigating the affect of electromagnetic noise by preventing actuation of the first (44,110)^(A) and second (44,110)^(B) safety restraint actuators if both the first 294 ^(A) and second 294 ^(B) signal conditioning circuits detect substantially the same signal, for example, as determined ratiometrically. More particularly, the noise rejection process 8000 commences with steps (8002) and (8004) which provide for detecting signals from the first 14 ^(A) and second 14 ^(B) coils, for example, from respective opposing doors 78 ^(A),78 ^(B) of the vehicle 12. Then, in step (8006), a ratio R of the respective signals from the first 294 ^(A) and second 294 ^(B) signal conditioning circuits. Then, in step (8008), if the magnitude of the ratio R is greater than a lower threshold Ro and less than an upper threshold R₁—which would occur responsive to an electromagnetic noise stimulus affecting both the first 10 ^(A) and second 10 ^(B) magnetic crash sensor—then the process repeats with step (8002), and neither the first (44,110)^(A) or second (44,110)^(B) safety restraint actuators are actuated. Otherwise, in step (8010), if the signal from the first magnetic crash sensor 10 ^(A) is greater than an associated crash threshold, and if, in step (8012), an associated safing condition is satisfied, then, in step (8014), the first safety restraint actuator (44,110)^(A) is actuated. Then, or otherwise from step (8010), in step (8016), if the signal from the second magnetic crash sensor 10 ^(B) is greater than an associated crash threshold, and if, in step (8018), an associated safing condition is satisfied, then, in step (8020), the second safety restraint actuator (44,110)^(B) is actuated.

Referring to FIGS. 81 and 82, in accordance with a sixth aspect of a signal conditioning circuit 800 that provides for generating one or more measures responsive to a self-impedance Z_(L) of a coil 14, L′, any of the magnetic crash sensors 10 described herein, including all of the above-described signal conditioning circuits 294, may be adapted to operate at a plurality of frequencies so as to provide for mitigating the affects of electromagnetic noise thereupon. More particularly, the oscillator 30, 50, 98 of any of the above-described embodiments may comprise a multi-frequency generator, for example, that generates either a simultaneous combination of a plurality of oscillatory waveforms, each at a different frequency f₁, f₂ . . . f_(N), or that generates a time-multiplexed combination of a plurality of oscillatory waveforms, each at a different frequency. For example, FIG. 81 illustrates a plurality of N oscillators 802.1, 802.2 . . . 802.N, for example, either digital or analog, each at a respective frequency f₁, f₂ . . . f_(N), wherein N is at least two. For a composite signal embodiment, the outputs of the N oscillators 802.1, 802.2 . . . 802.N are summed by a summer 804, either analog or digital, so as to generate a corresponding composite waveform, and the output therefrom, if digital, is converted to analog form by a digital-to-analog converter 806. For example, referring to FIG. 82, a composite analog multi-frequency signal may be generated by summing separate analog signals from N separate analog oscillators 802.1, 802.2 . . . 802.N using an inverting summing amplifier circuit 808 comprising an associated operational amplifier 810, which is DC biased by a DC common mode voltage signal V_(CM1). The multi-frequency signal is then used by the remaining portions 294′ of the above-described signal conditioning circuits 294 as the signal from the associated oscillator 30, 50, 98, wherein the associated filters of the associated remaining portions 294′ of the above-described signal conditioning circuits 294 would be designed to accommodate each of the associated frequencies f₁, f₂ . . . f_(N). The output voltage V_(OUT) from either the operational amplifier 278 of the associated summing and difference amplifier 276, or from the first differential amplifier 612, depending upon the particular signal conditioning circuit 294, is then converted to digital form by an analog-to-digital converter 288 after filtering with a low-pass anti-aliasing filter 286. The multi-frequency signal from the analog-to-digital converter 288 is then separated into respective frequency components by a group of digital filters 812.1, 812.2, . . . 812.N, for example, notch filters, each of which is tuned to the corresponding respective frequency f₁, f₂ . . . f_(N), the outputs of which are demodulated into respective in-phase I₁, I₂ . . . I_(N) and quadrature-phase Q₁, Q₂ . . . Q_(N) components by respective demodulators 290.1, 290.2, . . . 290.N, each of which is operatively coupled to the corresponding respective oscillator 802.1, 802.2 . . . 802.N. The output of the demodulators 290.1, 290.2, . . . 290.N is operatively coupled to a processor 108, 204 and used by a process 8300 to control the actuation of an associated safety restraint actuator 44, 110.

For example, referring to FIG. 83, in one embodiment of a process 8300 for controlling a safety restraint actuator 44, 110 responsive to signals from a multi-frequency embodiment of a magnetic crash sensor 10, the respective in-phase I₁, I₂ . . . I_(N) and quadrature-phase Q₁, Q₂ . . . Q_(N) components from the demodulators 290.1, 290.2, . . . 290.N are detected in steps (8302), (8304) and (8306) respectively, and are then processed in step (8400) so as to determine whether or not to actuate the associated safety restraint actuator 44, 110, after which the process repeats with step (8302).

Referring to FIG. 84, one embodiment of a sub-process 8400 for controlling a safety restraint actuator 44, 110 responsive to signals from a multi-frequency embodiment of a magnetic crash sensor 10 commences with step (8402), wherein a counter m is initialized to 1, a crash counter m_(CRASH) is initialized to zero, and if used, a noise counter m_(NOISE) is also initialized to zero. Then, in step (8404), if the signal SIGNAL_(m)—comprising in-phase I_(m) and quadrature-phase Q_(m) components—exceeds a corresponding crash threshold, then, in step (8406), the crash counter m_(CRASH) is incremented, and optionally, in step (8408), the associated frequency channel represented thereby is stored in an associated CrashID vector for use in subsequent processing. In an alternative supplemental embodiment, wherein a noise signal can be identified from a distinguishing characteristic of the signal SIGNAL_(m), then, from step (8404), if the signal SIGNAL_(m) exceeds a corresponding crash threshold, then, in step (8410), if the signal SIGNAL_(m) is identified as noise, then in step (8412), the noise counter m_(NOISE) is incremented, and optionally, in step (8414), the associated frequency channel represented thereby is stored in an associated NoiseID vector for use in subsequent processing. Otherwise, from step (8410), if the signal SIGNAL_(m) is not identified as noise, then the process continues with step (8406) as described hereinabove. Then, from either step (8408) or step (8414), or otherwise from step (8404), in step (8416), the counter m so as to set up for processing the next frequency component. Then, in step (8418), if the value of the counter m is greater than the total number N of frequency components, then in step (8420), the counter m is reset to one, a further sub-process (8500) or (8600) is called to determine whether or not to actuate the associated safety restraint actuator 44, 110, and the sub-process then returns control in step (8422). Otherwise, from step (8418), the process repeats with step (8404) until all frequency components have bee processed.

Referring to FIG. 85, in accordance with sub-process (8500) which provides for voting to determine whether or not to actuate the associated safety restraint actuator 44, 110, in step (8502), if for a majority of frequency components the signal SIGNAL_(m) has exceeded the corresponding crash threshold in step (8404), i.e. if the value of the crash counter m_(CRASH) exceeds half the total number N of frequency components, then, in step (8504), if the associated safing threshold is also exceeded by the signal from the associated safing sensor, then, in step (8506), the safety restraint actuator 44, 110 is actuated. Otherwise from either step (8502) or step (8504), or from step (8506), in step (8508), the crash counter m_(CRASH) is initialized to zero, and the sub-process returns control in step (8510). An odd number N of frequencies f₁, f₂ . . . f_(N) will prevent a tie in the associated voting process.

Alternatively, referring to FIG. 86, in a system for which a crash signal can be distinguished from noise on a channel-by-channel basis, if, in step (8602), the crash counter m_(CRASH) has a value greater than zero, or possibly greater than some other predetermined threshold, then, in step (8604), if the associated safing threshold is also exceeded by the signal from the associated safing sensor, then, in step (8606), the safety restraint actuator 44, 110 is actuated. Otherwise, or from step (8606), in step (8608), the crash counter m_(CRASH) and the noise counter m_(NOISE) are initialized to zero, and the sub-process returns control in step (8610).

The selection and separation of the frequencies f₁, f₂ . . . f_(N) is, for example, chosen so as to decrease the likelihood of simultaneous interference therewith by electromagnetic interference (EMI), which can arise from a number of sources and situations, including, but not limited to electric vehicle noise, telecommunications equipment, television receivers and transmitters, engine noise, and lightning. For example, in one embodiment, the frequencies are selected in a range of 25 KHz to 100 KHz. As the number N increases, the system approaches spread-spectrum operation.

It should be understood that frequency diversity may be used with any known magnetic sensor technology, including crash, safing or proximity detection that include but are not limited to systems that place a winding around the undercarriage, door opening or hood of the automobile, place a winding around the front fender of the automobile, placing a ferrite rod inside the hinge coil, or inside the striker coil for magnetic focusing, placing a ferrite rod coil in the gap or space between the doors, or placing a supplemental first coil on the side view rear molding which extends sideward away from the vehicle. This algorithm can also be used with signals that are generated by the magnetic sensor that set up alternate frequencies to create system safing on the rear door to enhance the system safing of the front door, AM, FM or pulsed demodulation of the magnetic signature multitone, multiphase electronics, a magnetically biased phase shift oscillator for low cost pure sine wave generation, a coherent synthetic or phase lock carrier hardware or microprocessor based system, a system of microprocessor gain or offset tuning through D/A then A/D self adjusting self test algorithms, placing a standard in the system safing field for magnetic calibration, inaudible frequencies, and the like.

It should also be understood that the performance of the coil 14, L′ used for either generating or sensing a magnetic field can be enhanced by the incorporation of an associated magnetic core of relatively high magnetic permeability. Furthermore, it should be understood that the particular oscillatory wave form of the oscillators is not limiting and could be for example a sine wave, a square wave, a saw tooth wave, or some other wave form of a single frequency, or a plural frequency that is either stepped or continuously varied or added together and sent for further processing therefrom.

It should be noted that any particular circuitry may be used such as that not limited to analog, digital or optical. Any use of these circuits is not considered to be limiting and can be designed by one of ordinary skilled in the art in accordance with the teachings herein. For example, where used, an oscillator, amplifier, or large scaled modulator, demodulator, and a deconverter can be of any known type for example using transistors, field effect or bipolar, or other discrete components; integrated circuits; operational amplifiers or logic circuits, or custom integrated circuits. Moreover, where used a microprocessor can be any computing device. The circuitry and software for generating, mixing demodulating and processing the sinusoidal signals at multiple frequencies can be similar to that used in other known systems.

Magnetic crash sensors and methods of magnetic crash sensing are known from the following U.S. Pat. Nos. 6,317,048; 6,407,660; 6,433,688; 6,583,616; 6,586,926; 6,587,048; 6,777,927; and 7,113,874; the following U.S. patent application Ser. Nos.: 10/666,165 filed on 19 Sep. 2003; and 10/905,219 filed on 21 Dec. 2004; and U.S. Provisional Application No. 60/595,718 filed on 29 Jul. 2005; all of which are commonly assigned to the Assignee of the instant application, and all of which are incorporated herein by reference.

Referring to FIGS. 87 and 88, in accordance with fourth 10.1 ^(iv) and fifth 10.1 ^(v) embodiments of the first aspect of a magnetic crash sensor 10.1 ^(iv), 10.^(v) adapted to sense a side impact crash, at least one coil 14, 72 is operatively associated with a first portion 76 of a door 78 of a vehicle 12, and is adapted to cooperate with at least one conductive element 80 that is operatively associated with, or at least a part of, a proximate second portion 82 of the door 78. The fourth 10.1 ^(iv) and fifth 10.1 ^(v) embodiments of the first aspect of a magnetic crash sensor 10.1″″ are similar to the third embodiment of the first aspect of a magnetic crash sensor 10.1′″ described hereinabove, except for the locations of the associated at least one coil 14, 72 and at least one of the associated at least one conductive element 80, respectively, wherein in the fourth embodiment 10.1 ^(iv), at least one coil 14, 72 is operatively associated with a portion of the vehicle that is subject to deformation responsive to a crash, and in the fifth embodiment 10.1 ^(v), at least one associated conductive element 80 is operatively associated with a portion of the vehicle that is relatively isolated from or unaffected by the crash for at least an initial portion of the crash.

For example, in the combination of the fourth 10.1 ^(iv) and fifth 10.1 ^(v) embodiments illustrated in FIGS. 87 and 88, the first portion 76 of the door 78 comprises the door beam 92 of the door 78, and the at least one conductive element 80 comprises either just a first conductive element 86 operatively associated with the inner panel 84 of the door 78 constituting a second portion 82 of the door 78; or first 86 and second 88 conductive elements at the inner panel 84 and outer skin 90 of the door 78, respectively, constituting respective second portions 82 of the door 78. For example, if the inner panel 84 of the door 78 were non-metallic, e.g. plastic, a first conductive element 86 could be operatively associated therewith, for example, either bonded or otherwise fastened thereto, so as to provide for cooperation there of with the at least one coil 14, 72. Alternatively, the inner panel 84, if conductive, could serve as the associated conductive element 80 without requiring a separate first conductive element 86 distinct from the inner panel 84 of the door 78; or the outer skin 90, if conductive, could serve as the associated conductive element 80 without requiring a separate second conductive element 88 distinct from the outer skin 90 of the door 78.

The at least one coil 14, 72 is electrically conductive and is adapted for generating a first magnetic field 94 responsive to a current applied by a coil driver 96, e.g. responsive to a first oscillatory signal generated by an oscillator 98. The magnetic axis 100 of the at least one coil 14, 72 is oriented towards the second portion 82 of the door 78—e.g. towards the inner panel 84 of the door 78, or towards both the inner panel 84 and outer skin 90 of the door 78, e.g. substantially along the lateral axis of the vehicle for the embodiment illustrated in FIGS. 87 and 88—so that the first magnetic field 94 interacts with the conductive elements 80, 86, 88 operatively associated therewith, thereby causing eddy currents 102 to be generated therein in accordance Lenz's Law. Generally the coil 14, 72 comprises an element or device that operates in accordance with Maxwell's and Faraday's Laws to generate a first magnetic field 94 responsive to the curl of an associated electric current therein, and similarly to respond to a time-varying first magnetic field 94 coupled therewith so as to generate a voltage or back-EMF thereacross responsive thereto, responsive to the reluctance of the magnetic circuit associated therewith. For example, the at least one coil 14, 72 may comprise a coil of wire of one or more turns, or at least a substantial portion of a turn, wherein the shape of the coil 14, 72 is not limiting, and may for example be circular, elliptical, rectangular, polygonal, or any production intent shape. For example, the coil 14, 72 may be wound on a bobbin, and, for example, sealed or encapsulated, for example, with a plastic or elastomeric compound adapted to provide for environmental protection and structural integrity. The resulting coil assembly may further include a connector integrally assembled, e.g. molded, therewith. Alternatively, the at least one coil 14, 72 may be formed by wire bonding, wherein the associated plastic coating is applied during the associated coil winding process.

For example, in one embodiment, an assembly comprising the at least one coil 14, 72 is positioned within the door 78 of the vehicle 12 so that the magnetic axis 100 of the at least one coil 14, 72 is substantially perpendicular to the inner panel 84 of the door 78, wherein the inner panel 84 is used as an associated sensing surface. Alternatively, the mounting angle relative to the inner panel 84 may be optimized to account for the shape of the associated metal surface and the relative proximity an influence of an associated door beam 92 or other structural elements relative to the inner panel 84.

In one embodiment, the radius of the coil 14, 72 is adapted to be similar to or greater than the initial distance to the principal or dominant at least one conductive element 80 being sensed thereby. The coil 14, 72 does not require any particular shape, and regardless of the shape, the associated effective sensing distance can be measured experimentally. The particular distance of the coil 14, 72 from the element or surface being sensed will depend upon the particular application. Generally, a range of mounting distances is possible. For example, the mounting distance may be determined by a combination of factors including, but not limited to, the conductivity of the conductive element, the coil size, the range of crash speeds that the coil is designed to sense before being damaged by contact with the conductive element, and the desired time to fire performance for specific crash events.

For example, in one embodiment, a coil 14, 72 of about 10 cm in diameter is located about 40 mm from the inner panel 84 of the door 78, which provides for monitoring about as much as 40 mm of stroke of coil 14, 72 motion, depending upon where along the length of the door beam 92 the coil 14, 72 is mounted and depending upon the door beam 92 intrusion expected during threshold ON (i.e. minimal severity for ON condition) and OFF (i.e. maximal severity for OFF condition) crash events for which the associated safety restraint actuator 44 should preferably be either activated or not activated, respectively. For example, in one embodiment, the location of the coil 14, 72 is adapted so that the associated motion thereof is relatively closely correlated to the bending of the door beam 92. For example, in an alternative mounting arrangement, the coil 14, 72 might be operatively associated with the outer skin 90 of the door 78 if the associated signal therefrom were sufficiently consistent and if acceptable to the car maker. For example, a CAE (Computer Aided Engineering) analysis involving both crash structural dynamics and/or electromagnetic CAE can be utilized to determine or optimized the size, shape, thickness—i.e. geometry—of the coil 14, 72 that both satisfies associated packaging requirements within the door 78 and provides sufficient crash detection capability. The position of the coil 14, 72 may be chosen so that a signal from the coil 14, 72 provides for optimizing responsiveness to a measure of crash intrusion for ON crashes, while also providing for sufficient immunity to OFF crashes, for both regulatory and real world crash modes. For example, the coil 14, 72 operatively associated with the door beam 92 may be adapted to be responsive to the inner panel 84, a conductive element 80, 86 operatively associated therewith, the outer skin 90, or a conductive element 80, 88 operatively associated therewith, either individually or in combination. The bending motion of the door beam 92 relative to the inner panel 84 has been found to be most reliable, however the initial motion of the outer skin 90 can be useful for algorithm entrance and for rapid first estimate of crash speed.

The position, size, thickness of the chosen sensor coil 14, 72 are selected to fit within the mechanical constraints of and within the door 78 associated with electrical or mechanical functions such as window movement, door 78 locks, etc.

For example, referring to FIGS. 89 and 90, in accordance with a first embodiment of a coil attachment, the coil 14, 72 is attached to a bracket 900 which is clamped between the door beam 92 and a lower portion 78′ of the door 78, so as to provide for operatively associating the coil 14, 72 with the door beam 92 so that the coil 14, 72 will move—i.e. rotate and translate—relative to the inner panel 84 of the door 78 responsive to an inward bending motion of the door beam 92 relative thereto responsive to a crash. The bracket 900 comprises a saddle portion 902 at a first end 900.1 thereof that shaped—, e.g. having a similarly shaped contour—so as to provide for engaging the door beam 92. A second end 900.2 of the bracket 900 is adapted to wedge into a lower portion 78′ of the door 78, for example, to engage a preexisting weep hole 904, an added hole, on an inboard side of the lower portion 78′ of the door 78. A central portion 900.3 of the bracket 900 is provided with a hollow portion 906 which is adapted with a bolt 908 that, when tightened, provides for collapsing the hollow portion 906 and thereby elongating the bracket 900, so that the bracket 900—with the coil 14, 72 attached thereto—becomes clamped between the door beam 92 and the lower portion 78′ of the door 78. For example, the coil 14, 72 may be attached to the bracket 900 using the bolt 908, wherein the coil 14, 72 is located on the side of the bracket 900 proximate to the inner panel 84 of the door 78. Accordingly, the coil 14, 72 is located below the window 910 and associated window guides 912 within the door 78. Alternatively, the second end 900.2 of the bracket 900 could be fastened to the lower portion 78′ of the door 78, for example, by bolting, riveting, welding or bonding, and the bracket 900 could be designed to bend allowing the coil 14, 72 to approach the inner panel 84 as the door beam 92 bends inwardly. Alternatively, the bracket 900 could be adapted to provide for connecting the first end 900.1 to the door beam 92 by either a scissors-type mechanism, or with a lip to provide for attachment thereto using a worm-gear type clamp at least partially around the door beam 92.

The bracket 900, for example, may be constructed of either a ferromagnetic material, e.g. steel, some other conductive material, e.g. aluminum, or a non-conductive material, e.g. plastic. A nonconductive bracket 900 could increase the coil sensitivity of the coil 14, 72 to relative motion of other conductive target structures while a conductive bracket 900 could provide directional shielding to lessen the signal from the coil 14, 72 responsive to conductive door structures on the side of the bracket 900. A bracket could be made of both materials, for example, a steel part that is welded to the beam and a plastic part that is bolted to the steel part to provide for easy attachment of the coil and bracket to the beam.

For another example, referring to FIG. 91, in accordance with a second embodiment of a coil attachment, the coil 14, 72 is attached to a bracket 914 that depends from the door beam 92, for example, by welding thereto, attachment to a flange dependent therefrom, or using any type locking clip-on or clamp technique that would cooperate with either a hole in the door beam 92 or a protrusion therefrom.

The bending of the door beam 92 responsive to a crash is relatively consistent and predictable, wherein the amount of bending is proportional to total crash energy and the rate of bending is proportional to crash speed. The material properties of the door beam 92, e.g. relatively high yield strength, provide for relatively more uniform beam flexing sustained over significant beam bending. Furthermore, the strength and end mounting of the door beam 92 provides for relatively similar bending patterns regardless of the location on the door beam 92 where a crash force is applied. Abuse impacts to the door by lower mass, higher speed objects will generally cause the primary door beam 92 to deflect a small amount, but possibly at an initially high rate of speed. Abuse impacts to the door by higher mass, low speed objects may result in larger total main door beam 92 deflections, but at a substantially lower rate of the deflection. Mechanical abuse events can be ignored using a signal from the coil 14, 72—moving with the door beam 92—responsive to the inner panel 84 of the door 78. Although, the coil 14, 72 can be located almost anywhere along the door beam 92, locating the coil 14, 72 near the center third of the door beam 92 will provide the most consistent response. Also, locating the coil 14, 72 relatively near the center of the door beam 92 will provide for a more rapid displacement of the coil 14, 72 toward the inner panel 84 so as to provide a more rapid increase in the signal-to-noise ratio of the signal from the coil 14, 72 during a crash event. Rotation of the door beam 92 during the crash stroke, resulting from the off-axis inertia of the coil 14, 72 and its bracket 914, can be reduced by reducing the mass of the coil 14, 72 and bracket 914, and by locating their combined center of mass relatively close to the height of the center of the door beam 92, while avoiding interference with internal parts of the door 78. Furthermore, rotation of the door beam 92 and deflection of the bracket 914 during a relatively high acceleration of the door beam 92 during an ON crash event can be reduced if the bracket 914 attaching the coil 14, 72 to the door beam 92 is made of a relatively high stiffness but low mass material. Generally, a pole crash would engage the door beam 92 for almost any impact location along the door and most cars are designed so that the door beam 92 will engage the bumpers of regulatory MDB (Moving Deformable Barrier) impacts, making motion of the door beam 92 a reliable indicator of crash severity for many crash types.

Furthermore, the region below the door beam 92 in many doors 78 is relatively unused, often providing ample space for packaging a coil 14, 72 that will not conflict with existing/future door design and interior equipment. More particularly, in this location, the door window glass 910 would typically not constrain the placement of the coil 14, 72 relative to the surface(s) to be sensed, so the size (and cost) of the coil 14, 72 can be reduced and the coil-to-target initial distance can be optimized to give a larger signal (increased SNR) during the sensing time.

Yet further, a coil 14, 72 in cooperation with the inner panel 84 of the door 78 can provide for relatively less susceptibility to motion of metal inside the vehicle cabin in comparison with a coil operatively coupled to the inner panel 84 if near an access hole.

However, a system using a coil 14, 72 attached to the door beam 92 may be susceptible to delayed or inconsistent performance when an impacting vehicle has a bumper that is sufficiently high so as to not directly engage the door beam 92 during a collision therewith. Furthermore, vibration of the coil 14, 72 attached to the door beam 92 during operation of the vehicle may need to be controlled. For some door beam 92 cross-sectional profiles, for example, cross-sectional profiles that are not substantially curved or round, such as rectangular or square cross-sectional profiles, the associated door beam 92 may exhibit either unacceptable or unpredictable rotation during variable impacts such that a coil 14, 72 attached thereto may not provide a consistent and reliable signal for determining crash severity, particularly if the coil 14, 72 is not mounted sufficiently near the height of the center of the door beam 92.

The magnetic crash sensor 10.1 ^(iv), 10.1 ^(v) may be adapted to sense both the motion of the outer skin 90 of the door moving towards the coil 14, 72 and the motion of the coil 14, 72 towards the inner panel 84, which would provide for a relatively rapid signal to “wake-up” the sensing system, provide a relatively quick indication of the speed of impact (e.g. rate of movement of the outer skin 90), and so as to provide a relatively more complex, feature-right signal that would be a superposition of signals responsive to both associated relative motions, but for which it is relatively more difficult to ascribe physical meaning to the associated response, and which would be more susceptible to mechanical abuse events of the vehicle.

Alternatively, magnetic crash sensor 10.1 ^(iv) may be adapted to principally sense primarily only the relative motion of the door beam 92 relative to the inner panel 84, in which case, the coil 14, 72 would be magnetically shielded or decoupled from the outer skin 90, for example, by incorporating a magnetic shield (which, for example, may also include an eddy current shield as described herein above) into the bracket so as to reduce the magnetic communication between the coil 14, 72 and the outer skin 90 of the door 78 or by initially placing the coil 14, 72 substantially closer to the inner panel 84 than to the outer skin 90 so that motion of the outer skin 90 causes only a relatively small change in the signal from the coil 14, 72. Such an arrangement would be expected to provide a relatively delayed response during impact—relative to the arrangement that is adapted to also be responsive to the outer skin 90—but which would exhibit a relative high immunity to abuse events—e.g. that would either not cause significant total bending or would not cause a high bending rate of the door beam 92—whereby a crash could be discriminated responsive to an associated rate of motion in combination with a minimum or measure of total bending. Such an arrangement would provide for a relatively simple physical interpretation of the associated signals as being related to bending of the door beam 92 and the associated intrusion thereof towards the inner panel 84.

The conductive elements 86, 88 each comprise, for example, a thin metal sheet, film or coating, comprising either a paramagnetic or diamagnetic material that is relatively highly conductive, e.g. aluminum or copper, and which, for example, could be an integral part of the second portion 82 of the door 78. For example, the conductive elements 86, 88 could be in the form of relatively thin plates, a film, a tape (e.g. aluminum or copper), or a coating that is mounted on, applied to, or integrated with existing or supplemental structures associated with the inner panel 84 and the inside surface of the outer skin 90 of the door 78 respectively.

The frequency of the oscillator 98 is adapted so that the corresponding oscillating magnetic field generated by the at least one coil 14, 72 both provides for generating the associated eddy currents 102 in the conductive elements 86, 88, and is magnetically conducted through the ferromagnetic elements of the door 78 and proximate structure of the vehicle 12.

The at least one coil 14, 72 is responsive to both the first magnetic field 94 generated by the at least one coil 14, 72 and a second magnetic field 104 generated by the eddy currents 102 in the conductive elements 86, 88 responsive to the first magnetic field 94. The self-impedance of the coil 14, 72 is responsive to the characteristics of the associated magnetic circuit, e.g. the reluctance thereof and the affects of eddy currents in associated proximal conductive elements. Accordingly, the coil 14, 72 acts as a combination of a passive inductive element, a transmitter and a receiver. The passive inductive element exhibits self-inductance and self resistance, wherein the self-inductance is responsive to the geometry (coil shape, number of conductors, conductor size and cross-sectional shape, and number of turns) of the coil 14, 72 and the permeability of the associated magnetic circuit to which the associated magnetic flux is coupled; and the self-resistance of the coil is responsive to the resistivity, length and cross-sectional area of the conductors constituting the coil 14, 72. Acting as a transmitter, the coil 14, 72 generates and transmits a first magnetic field 94 to its surroundings, and acting as a receiver, the coil 14, 72 generates a voltage responsive to a time varying second magnetic field 104 generated by eddy currents in associated conductive elements within the surroundings, wherein the eddy currents are generated responsive to the time varying first magnetic field 94 generated and transmitted by the coil 14, 72 acting as a transmitter. The signal generated by the coil 14, 72 responsive to the second magnetic field 104 received by the coil 14, 72, in combination with the inherent self-impedance of the coil 14, 72, causes a complex current within or voltage across the coil 14, 72 responsive to an applied time varying voltage across or current through the coil 14, 72, and the ratio of the voltage across to the current through the coil 14, 72 provides an effective self-impedance of the coil 14, 72, changes of which are responsive to changes in the associated magnetic circuit, for example, resulting from the intrusion or deformation of proximal magnetic-field-influencing—e.g. metal—elements.

The at least one coil 14, 72 is operatively coupled to a signal conditioner/preprocessor circuit 114, which, for example, provides for preamplification, filtering, synchronous demodulation, and analog to digital conversion of the associated signal(s) therefrom, e.g. as described hereinabove. The signal conditioner/preprocessor circuit 114 is operatively coupled to a processor 116 which processes the signal therefrom, thereby providing for discriminating a crash, and controlling an associated safety restraint actuator 110—e.g. a side air bag inflator—operatively coupled thereto. More particularly, the signal conditioner/preprocessor circuit 114 provides for determining a measure responsive to the self-impedance of the at least one coil 14, 72 responsive to an analysis of the complex magnitude of the signal from the at least one coil 14, 72, for example, in relation to the signal applied thereto by the associated oscillator 98. For example, in one embodiment, the signal conditioner/preprocessor circuit 114, coil driver 96, oscillator 98 and processor 108 are incorporated in an electronic control unit 120 that is connected to the at least one coil 14, 72 with standard safety product cabling 122, which may include associated connectors.

In operation, the magnetic crash sensor 10.1 ^(iv), 10.1 ^(v) provides a measure of the relative motion of the door beam 92 relative to the inner panel 84 and/or the outer skin 90 of the door 78, for example, as caused by a crushing of the outer skin 90 of the door 78 or the bending of the door beam 92 responsive to a side-impact of the vehicle 12. During non-crash conditions, an oscillating magnetic field resulting from the combination of the first 94 and second 104 magnetic fields would be sensed by the at least one coil 14, 72. If an object impacted the outer skin 90 of the door 78 causing a physical deflection thereof, then this oscillating magnetic field would be perturbed at least in part by changes in the second magnetic field 104 caused by movement or deformation of the associated first conductive element 80, 86 and the associated changes in the associated eddy currents 102 therein. If the impact is of sufficient severity, then the door beam 92 and the associated coil 14, 72 would also be moved or deformed thereby, causing additional changes in the associated eddy currents 102 in the first conductive element 80, 86 and the corresponding second magnetic field 104. Generally, the door beam 92 would not be significantly perturbed during impacts that are not of sufficient severity to warrant deployment of the associated safety restraint actuator 110, notwithstanding that there may be substantial associated deformation of the outer skin 90 of the door 78. Accordingly, in one embodiment, a magnetic crash sensor 10.1 ^(iv) might incorporate the first conductive element 88, and not the first conductive element 86.

Responsive to a crash with an impacting object of sufficient energy to deform the at least one conductive element 80, changes to the shape or position of the at least one conductive element 80 relative to the at least one coil 14, 72, or vice versa, affect the magnetic field affecting the at least one coil 14, 72. A resulting signal is preprocessed by the signal conditioner/preprocessor circuit 114, which provides for measuring the signal across the at least one coil 14, 72 and provides for measuring the signal applied thereto by the associated coil driver 96. The signal conditioner/preprocessor circuit 114—alone, or in combination with another processor 116—provides for decomposing the signal from the at least one coil 14, 72 into real and imaginary components, for example, using the signal applied by the associated coil driver 96 as a phase reference.

Referring to FIGS. 92 a, 92 b and 93, in accordance with a first embodiment of a fourth aspect 10.4, a magnetic sensor 10 operatively associated with a vehicle 12 comprises a plurality of coil elements 14 electrically connected in series and distributed across a sensing region 1016 adapted so as to cooperate with various associated different portions 20.1, 20.2, 20.3, 20.4 and 20.k of the vehicle 12. The various coil elements 14 can be either non-overlapping as illustrated in FIG. 92 a, over-lapping as illustrated in FIG. 92 b, or, as illustrated in FIG. 92 c, some of the coil elements 14 (L₁′, L₂′) may be overlapping, and other of the coil elements (L₃′, L₄′, . . . L_(K)′) may be non-overlapping. A time-varying signal source 1020 comprising a signal generator 1022 generates at least one time-varying signal 1024 that is operatively coupled to the plurality of coil elements 14, for example, through a coil driver 202. For example, referring to FIG. 93, in accordance with the first embodiment, the plurality of coil elements 14 comprise a plurality of k conductive coil elements L₁′, L₂′, L₃′, L₄′, . . . L_(K)′, each of which can be modeled as an associated self-inductance L₁, L₂, L₃, L₄, . . . L_(K), in series with a corresponding resistance R₁, R₂, R₃, R₄ . . . R_(K). The plurality of coil elements 14 are connected in series, a time-varying voltage signal v from a time-varying voltage source 1020.1 applied across the plurality of coil elements 14 through a sense resistor R_(S), which causes a resulting current i to flow through the associated series circuit 242. Each of the associated coil elements L₁′, L₂′, L₃′, L₄′, . . . L_(K)′ generates an associated magnetic field component 140.1, 140.2, 140.3, 140.4, . . . 140.k responsive to the geometry thereof and to the current i therethrough. The associated magnetic field components 140.1, 140.2, 140.3, 140.4, . . . 140.k interact with the associated different portions 20.1, 20.2, 20.3, 20.4 and 20.k of the vehicle 12, which affects the effective impedance Z₁, Z₂, Z₃, Z₄, . . . Z_(K) of the associated coil elements L₁′, L₂′, L₃′, L₄ . . . L_(K)′, thereby affecting the complex magnitude of the associated current i through the associated series circuit 242. A detection circuit 1032.1 comprising a signal conditioner/preprocessor circuit 114 senses the current i through each of the plurality of coil elements 14 from an associated voltage drop across the sense resistor R_(S). The at least one time-varying signal 1024, or a signal representative thereof from the signal generator 1022, and a signal from the signal conditioner/preprocessor circuit 114 at least representative of the response current i, are operatively coupled to a processor 204 of the detection circuit 1032.1 which provides for determining a detected signal 1038 comprising a measure responsive to the impedance Z₁, Z₂, Z₃, Z₄, . . . Z_(K) of the associated coil elements L₁′, L₂′, L₃′, L₄′, . . . L_(K)′, responsive to which a controller 1040 provides for controlling an actuator 1042, either directly or in combination with a second confirmatory signal from a second sensor, e.g. a second crash sensor, or for providing associated information to the driver or occupant of the vehicle 12, or to another system. For example, the actuator 1042 may comprise a safety restraint system, e.g. an air bag inflator (e.g. frontal, side, overhead, rear, seat belt or external), a seat belt pretensioning system, a seat control system, or the like, or a combination thereof.

With the plurality of coil elements 14 connected in series, the current i through the series circuit 242, and the resulting detected signal 1038, is responsive associated sensed signal components from each of the coil elements L₁′, L₂′, L₃′, L₄′, . . . L_(K)′, wherein each sensed signal component would correspond to the associated respective impedance Z₁, Z₂, Z₃, Z₄, . . . Z_(K) of the respective coil element L₁′, L₂′, L₃′, L₄′, . . . L_(K)′, wherein the associated respective impedances Z₁, Z₂, Z₃, Z₄, . . . Z_(K) of the associated coil elements L₁′, L₂′, L₃′, L₄′, . . . L_(K)′ are responsive to the associated respective magnetic field components 140.1, 140.2, 140.3, 140.4, . . . 140.k responsive to the associated interactions of the respective coil elements L₁′, L₂′, L₃′, L₄′, . . . L_(K)′ with the respective different portions 20.1, 20.2, 20.3, 20.4 and 20.k of the vehicle 12. Accordingly, the detected signal 1038 provides for detecting a change in a magnetic condition of, or associated with, the vehicle 12, for example, as might result from either a crash or a proximate interaction with another vehicle. The plurality of coil elements are adapted to span a substantial region 1044 of a body or structural element 1046 of the vehicle 12, wherein the body or structural element 1046 of the vehicle 12 is susceptible to deformation responsive to a crash, or is susceptible to some other interaction with another vehicle that is to be detected. Accordingly, a detected signal 1038 responsive to the current i through the plurality of coil elements 14 distributed over a substantial region 1044 of a body or structural element 1046 of the vehicle 12, in a series circuit 242 driven by a time-varying voltage signal v across the series combination of the plurality of coil elements 14, provides for detecting from a single detected signal 1038 a change in a magnetic condition of, or associated with, the vehicle 12 over the associated substantial region 1044 of the body or structural element 1046 of the vehicle 12, so as to provide for a magnetic sensor 10 with relatively broad coverage.

In accordance with a fifth aspect 10.5 of the magnetic sensor 10, a plurality of response signals are measured each responsive to different coil elements L₁′, L₂′, L₃′, L₄′, . . . L_(K)′ or subsets thereof. Referring to FIG. 94, in accordance with a first embodiment of the fifth aspect 10.5 of the magnetic sensor 10, the time-varying signal source 1020 comprises a time-varying current source 1020.2, and the associated detection circuit 1032.2 is responsive to at least one voltage signal v₁, v₂, v₃, v₄, . . . v_(K) across at least one of the corresponding coil elements L₁′, L₂′, L₃′, L₄′, . . . L_(K)′. For example, in the first embodiment illustrated in FIG. 94, each of the voltage signals v₁, v₂, v₃, v₄, . . . v_(K) across each of the corresponding coil elements L₁′, L₂′, L₃′, L₄′, . . . L_(K)′ is measured by the detection circuit 1032.2, for example, by an associated processor 204 incorporating associated signal conditioner and preprocessor circuits 114, e.g. corresponding differential amplifiers 1048 and A/D converters 1050 operatively coupled across each of the coil elements L₁′, L₂′, L₃′, L₄′, . . . L_(K)′, so as to provide for generating at least one detected signal 1038 responsive to the impedances Z₁, Z₂, Z₃, Z₄ . . . . Z_(K) of the associated respective coil elements L₁′, L₂′, L₃′, L₄′, . . . L_(K)′.

Referring to FIG. 95, in accordance with a second embodiment of the fifth aspect 10.5 of the magnetic sensor 10, the plurality of coil elements 14 connected in a series circuit 242 are driven by a time-varying voltage source 1020.1 comprising a signal generator 221022 operatively coupled to a coil driver 202. The current i through the series circuit 242 is measured by the processor 204 from the voltage drop across a sense resistor R_(S) in the series circuit 242, conditioned by an associated signal conditioner/preprocessor circuit 114 operatively coupled to the processor 204. Each of the voltage signals v₁, v₂, v₃, v₄, . . . v_(K) across each of the coil elements L₁′, L₂′, L₃′, L₄′, . . . L_(K)′ are also measured by the processor 204 using associated signal conditioner and preprocessor circuits 114 operatively coupled therebetween, so as to provide for measuring—i.e. at least generating a measure responsive to—the corresponding impedances Z₁, Z₂, Z₃, Z₄, . . . Z_(K) of each of the corresponding respective coil elements L₁′, L₂′, L₃′, L₄′, . . . L_(K)′, so as to provide for generating a measure responsive to the localized magnetic conditions of, or associated with, the vehicle 12 over the associated substantial region 1044 of the body or structural element 1046 of the vehicle 12 associated with the different portions 20.1, 20.2, 20.3, 20.4 and 20.k of the vehicle 12 associated with the corresponding respective coil elements L₁′, L₂′, L₃′, L₄′, . . . L_(K)′.

The at least one time-varying signal 1024 from the time-varying signal source 1020 may comprise either an oscillatory or pulsed waveform. For example, the oscillatory waveform may comprise a sinusoidal waveform, a triangular ramped waveform, a triangular sawtooth waveform, a square waveform, or a combination thereof, at a single frequency or a plurality of different frequencies; and the pulsed waveform may comprise any of various pulse shapes, including, but not limited to, a ramp, a sawtooth, an impulse or a rectangle, at a single pulsewidth or a plurality of different pulsewidths. Frequency diversity techniques can provide information about deformation depth or deformation rate of the associated different portions 20.1, 20.2, 20.3, 20.4 and 20.k of the vehicle 12 being sensed, and can also provide for improve electromagnetic compatibility and immunity to external electromagnetic noise and disturbances.

Referring to FIG. 96, in accordance with the first embodiment of the fourth aspect 10.4 of the magnetic sensor 10, a plurality of plurality of coil elements 14 electrically in series with one another constituting a distributed coil 124 operatively associated with, or mounted on, an associated substrate 138 are illustrated operating in proximity to a magnetic-field-influencing object 1064—e.g. either ferromagnetic, conductive, or a combination thereof—constituting either a second portion 20, 82 of a vehicle 12, or at least a portion of an object 1064′ distinct the vehicle 12, e.g. a portion of another vehicle. Referring also to FIG. 92, different coil elements L₁′, L₂′, L₃′, L₄′, . . . L_(K)′ are adapted with different geometries, e.g. different associated numbers of turns or different sizes, so as to provide for shaping the associated magnetic field components 140.1, 140.2, 140.3, 140.4, . . . 140.k, so as to in shape the overall magnetic field 140 spanning the sensing region 1016, for example, so that the associated magnetic field components 140.1, 140.2, 140.3, 140.4, . . . 140.k are stronger—e.g. by using a greater number of turns for the associated coil elements L₁′, L₂′, L₃′, L₄′, . . . L_(K)′—proximate to different portions 20.1, 20.2, 20.3, 20.4 and 20.k that are nominally less magnetically influential on the associated impedances Z₁, Z₂, Z₃, Z₄, . . . Z_(K) of the associated different coil elements L₁′, L₂′, L₃′, L₄′, . . . L_(K)′, than other coil elements L₁′, L₂′, L₃′, L₄′, . . . L_(K)′. For example, in the embodiment illustrated in FIG. 92, coil elements L₁′, L₂′ and L_(K)′ are illustrated each comprising one turn, coil element L₃′ is illustrated comprising two turns, and coil element L₄′ is illustrated comprising three turns, wherein the number of turns is inversely related to the relative proximity of the associated corresponding different portions 20.1, 20.2, 20.3, 20.4 and 20.k of the vehicle 12 to the corresponding coil elements L₁′, L₂′, L₃′, L₄′, . . . L_(K)′, respectively. Accordingly, the plurality of coil elements 14 are adapted so as to provide for shaping the associated magnetic field 140 responsive to at least one magnetic-field influencing property of at least one second portion 20, 82 of the vehicle 12 in proximity to the plurality of coil elements 14. The shaping of the composite distributed magnetic field 140 provides for normalizing the affect of a change in the associated magnetic condition of the associated magnetic-field-influencing object 1064 being sensed over the length or area of the associated sensing region 1016, and also provides for increasing the sensitivity of the magnetic sensor 10 in locations where necessary, and/or decreasing the sensitivity of the magnetic sensor 10 in other locations where necessary.

Referring again to FIGS. 11 a, 11 b, 12, 13, 14 a, 14 b, 15 a, 15 b, 16, 17 a and 17 b, it should be appreciated that the various embodiments of the coils 14.2-14.8 illustrated therein can also be used as the distributed coil 124 in accordance with the fourth aspect 10.4 of the magnetic sensor 10, so as to provide for a set of an associated plurality of coil elements 14 that are electrically connected in series and distributed across a sensing region 1016 adapted so as to cooperate with various associated different portions 20.1, 20.2, 20.3, 20.4 and 20.k of the vehicle 12.

Referring to FIG. 97, in accordance with a sixth aspect 10.6 of the magnetic sensor 10, the plurality of coil elements 14 are grouped into a plurality of subsets 1078, for example, in an embodiment thereof, first 1078.1, second 1078.2 and third 1078.3 subsets of coil elements 14, wherein the coil elements 14 in each subset 1078 are connected in series, a series combination of the first 1078.1 and second 1078.2 subsets of coil elements 14 are driven by a first time-varying signal source 1080.1, i.e. a first time-varying voltage source 1080.1, comprising a first coil driver 202.1 driven by a first signal generator 1022.1, and the third subset 1078.3 of coil elements 14—electrically separated from the first 1078.1 and second 1078.2 subsets—is driven by a second time-varying signal source 1080.2, i.e. a second time-varying voltage source 1080.2, comprising a second coil driver 202.2 driven by a second signal generator 1022.2. A first time-varying voltage signal v.1 from the first time-varying voltage source 1080.1 generates a first current i.1 in the series combination of the first 1078.1 and second 1078.2 subsets of coil elements 14, which is sensed by a first signal conditioner/preprocessor circuit 114.1 responsive to the associated voltage drop across a first sense resistor R_(S1). The first subset 1078.1 of coil elements 14 comprises a series combination of two coil elements L₁′ and L₂′, across which a second signal conditioner/preprocessor circuit 114.2 provides for measuring a voltage drop thereacross, which together with the first current i.1, provides for an associated processor 204 to generate a measure of the impedance Z₁ of the first subset 1078.1 of coil elements 14. Similarly, the second subset 1078.2 of coil elements 14 comprises a series combination of two coil elements L₃′ and L₄′, across which a third signal conditioner/preprocessor circuit 114.3 provides for measuring a voltage drop thereacross, which together with the first current i.1, provide for the associated processor 204 to generate a measure of the impedance Z₂ of the second subset 1078.2 of coil elements 14. A second time-varying voltage signal v.2 from the second time-varying voltage source 1080.2 generates a second current i.2 in the third subset 1078.3 of coil elements 14, which is sensed by a fourth signal conditioner/preprocessor circuit 114.4 responsive to the associated voltage drop across a second sense resistor R_(S2). The third subset 1078.3 of coil elements 14 comprises a series combination of three coil elements L₅′, L₆′ and L₇′, across which a fifth signal conditioner/preprocessor circuit 114.5 provides for measuring a voltage drop thereacross, which together with the second current i.2, provides for an associated processor 204 to generate a measure of the impedance Z₃ of the third subset 1078.3 of coil elements 14. Accordingly, the sixth aspect 10.6 of the magnetic sensor 10 provides for applying different time-varying signals 24 to different subsets 1078 of coil elements 14, wherein the different time-varying signals 24 may comprise different magnitudes, waveforms, frequencies or pulsewidths, etc. The sixth aspect 10.6 of the magnetic sensor 10 also provides for measuring a plurality of impedances Z of a plurality of different subsets 1078 of coil elements 14, so as to provide for localized measures of the associated magnetic condition of the vehicle 12. The associated voltage measurements associated with the corresponding impedance measurements can be either simultaneous or multiplexed. Furthermore, the magnetic sensor 10 may be adapted so as to provide for measurements of both individual subsets 1078 of coil elements 14 and of the overall series combination of a plurality of subsets 1078 of coil elements 14, wherein the particular measurements may be chosen so as to provide localized measurements of some portions 20 of the vehicle 12 in combination with an overall measurement to accommodate the remaining portions 20, so as to possibly provide for a spatial localization of perturbations to the magnetic condition of the vehicle 12, or the rate of deformation or propagation of a magnetic disturbance, for example, as may result from a crash or proximity of another vehicle. It should be understood that a variety of measures may be used by the associated detection circuit 32, for example, impedance Z, a voltage signal from the associated signal conditioner/preprocessor circuit 114, or in-phase and/or quadrature-phase components of the voltage signal from the associated signal conditioner/preprocessor circuit 114. For example, a comparison of the ratio of a voltage from a subset 1078 of coil elements 14 to the voltage across the entire associated distributed coil 124 can provide for mitigating the affects of noise and electromagnetic susceptibility.

Referring to FIG. 98, in accordance with an embodiment of a seventh aspect 10.7 of a magnetic sensor 10, the plurality of coil elements 14 are arranged in a two-dimensional array 1082 on a substrate 138 so as to provide for sensing a change in a magnetic condition of the vehicle 12 over an associated two-dimensional sensing region 1084. For example, in accordance with a first embodiment, the two-dimensional array 1082 comprises m rows 1086 and n columns 1088 of associated coil elements 14, wherein different columns 1088 are at different X locations, and different rows 1086 are at different Y locations of a Cartesian X-Y coordinate system. In the first embodiment, the m x n two-dimensional array 1082 is organized in a plurality of subsets 1078, for example, a first subset 1078.1 comprising rows 1086 numbered 1 and 2 of the two-dimensional array 1082, the next n subsets 1078.3-1078.3+n respectively comprising the individual coil elements 14 of the third row 1086, and the last subset 1078.x comprising the last (m^(th)) row of the two-dimensional array 1082. Each subset 1078 comprises either a single coil element 14 or a plurality of coil elements 14 connected in series, and provides for a relatively localized detection of the magnetic condition of the vehicle 12 responsive to the detection of an associated measure responsive to the impedance Z of the associated subset 1078 of coil elements 14, using a detection circuit 32, for example, similar to that described hereinabove in accordance with other embodiments or aspects of the magnetic sensor 10. It should be understood that the plurality of coil elements 14 in accordance with the seventh aspect 10.7 of a magnetic sensor 10 need not necessarily be arranged in a Cartesian two-dimensional array 1082, but alternatively, could be arranged in accordance with some other pattern spanning a two-dimensional space, and furthermore, could also be arranged so in accordance with a pattern spanning a three-dimensional space, for example, by locating at least some coil elements 14 at different distances from an underlying reference surface. The geometry—e.g. shape, size, number of turns, or conductor size or properties—of a particular coil element 14 and the associated substrate 138 if present can be adapted to provide for shaping the overall magnetic field 140 spanning the sensing region 1016. For example, the coil elements 14 can be formed on or constructed from a flexible printed circuit board (PCB) or other flexible or rigid flat mounting structure, and, for example, the resulting assembly 1090 of coil elements 14 may be encapsulated for environmental protection or to maintain the necessary shape and/or size for proper operability thereof in cooperation with the vehicle 12. Different subsets 1078 of coil elements 14 may be driven with different time-varying signals 24, for example, each with an associated waveform or pulse shape, frequency, frequency band or pulse width, and amplitude adapted to the particular subset 1078 of coil elements 14 so as to provide for properly discriminating associated crash events or proximate objects as necessary for a particular application.

The fourth through seventh aspects 10.4-10.7 of the magnetic sensor 10 provides for detecting deformation and/or displacement of associated at least one magnetic-field-influencing object 1064 constituting portions 20 of the vehicle 12 responsive to a crash, and/or provides for detecting the proximity or approach of an approaching or proximate external magnetic-field-influencing object 1064, within the sensing range of at least one coil elements 14 of the plurality of coil elements 14 distributed across either one-, two- or three-dimensional space. The plurality of coil elements 14 driven by at least one time-varying signal 1024 exhibit a characteristic complex impedance Z which is affected and changed by the influence of a proximate magnetic-field-influencing object 1064 and/or deformation or displacement of associated magnetic-field-influencing portions 20′ of the vehicle 12 in proximate operative relationship to coil elements 14 of the plurality of coil elements 14. Measurements of the voltage v across and current i through the coil elements 14 provide associated time varying sensed signals 1094 that provide for generating at least one detected signal 1038 responsive thereto and responsive to, or a measure of, the associated complex impedance Z of the associated plurality or pluralities of coil elements 14 or subsets 1078 thereof, which provides for a measure responsive to the dynamics of an approaching external magnetic-field-influencing object 1064, 1064′ (e.g. metal, metalized or ferromagnetic), or responsive to the dynamics of deformation of the at least one magnetic-field-influencing object 1064 constituting portions 20 of the vehicle 12 responsive to a crash, and which are in operative proximate relationship to the plurality or pluralities of coil elements 14 or subsets 1078 thereof. The time varying sensed signals 1094 are responsive to ferromagnetic and eddy current affects on the associated complex impedance Z of each of the associated plurality or pluralities of coil elements 14 or subsets 1078 thereof spanning a substantial region 1044 of a body or structural element 1046 to be sensed.

In accordance with an aspect of the magnetic sensor 10, either the geometry of first L₁′ and at least second L₂′ coil elements associated with different first 20.1 and at least second 20.2 portions of the vehicle 12, the associated at least one time-varying signal 1024, or an associated at least one detection process of an associated at least one detection circuit 32, are adapted so as to provide that a first response of the at least one detection circuit 32 to a first sensed signal component from a first coil element L₁′ is substantially normalized—e.g. with respect to respective magnitudes or signal-to-noise rations of the associated sensed signal components—with respect to at least a second response of the at least one detection circuit 32 to at least a second sensed signal component from at least the second coil element L₂′ for a comparably significant crash or proximity stimulus or stimuli affecting the first 20.1 and at least second 20.2 portions of the vehicle 12. Accordingly, in addition to being distributed over a region of space associated with an associated sensing region 1016, for an associated sensing region 1016 spanning different portions 20.1, 20.2, 20.3, 20.4 and 20.k of the vehicle 12 that are magnetically different in their associated influence on the associated plurality of coil elements 14, at least one of at least one geometry of the plurality of coil elements 14, the at least one time-varying signal 1024, and at least one detection process is adapted so that at least one of a first condition, a second condition and a third condition is satisfied so as to provide that a first response of the at least one detection circuit 32 to a first sensed signal component from a first coil element L₁′ is substantially normalized with respect to at least a second response of the at least one detection circuit 32 to at least a second sensed signal component from at least the second coil element L₂′ for a comparably significant crash stimulus or stimuli affecting the first 20.1 and at least second 20.2 portions of the vehicle 12.

The first condition is satisfied if the geometry—e.g. the size, shape, or number of turns—of the first L₁′ and at least a second L₂′ coil element are different. For example, referring to FIG. 92, the first coil element L₁′ being relatively closer in proximity to the corresponding first portion 20.1 of the vehicle 12 has fewer turns than the corresponding third L₃′ or fourth L₄′ coil elements which are relatively further in proximity to the corresponding third 20.3 and fourth 20.4 portions of the vehicle 12, respectively.

The second condition is satisfied if a first time-varying signal 1024.1 operatively coupled to a first coil element L₁′ is different from at least a second time-varying signal 1024.2 operatively coupled to at least a second coil element L₂′. For example, referring to FIG. 97 or 98, at least two different coil elements 14 or subsets 1078 thereof are driven by different associated time-varying signal sources 1080.1 and 1080.2. If the associated different coil elements 14 each have substantially the same geometry, but have a different magnetic coupling to the associated first 20.1 and at least second 20.2 different portions of the vehicle 12, e.g. as illustrated in FIG. 92, then different coil elements 14 could be driven with different associated levels of the associated time-varying signals 24.1 and 24.2, e.g. a coil element 14 of closer proximity to the associated portion 20 of the vehicle 12 being driven at a lower voltage than a coil element 14 of further proximity, so that strength of the associated corresponding magnetic field components 140.1, 140.2 are inversely related to the associated magnetic coupling, so that the affect on the detected signal 1038 of a change in the first portion 20.1 of the vehicle 12 is comparable to the affect on the detected signal 1038 of a change in the second portion 20.2 of the vehicle 12 for each change corresponding to a relatively similar crash or proximity stimulus or stimuli affecting the first 20.1 and at least second 20.2 portions of the vehicle 12.

The third condition is satisfied if a first detection process of the at least one detection circuit 32 operative on a first sensed signal component from or associated with a first coil element L₁′ is different at least a second detection process of the at least one detection circuit 32 operative on at least a second sensed signal component from or associated with at least a second coil element L₂′. For example, the associated signal gain associated with processing different signals from different coil elements 14 can be different, e.g. the signal from a coil element 14 of closer proximity to an associated first portion 20.1 of the vehicle 12 could be amplified less than the signal from a coil element 14 of further proximity to an associated second portion 20.2 of the vehicle 12, so that the affect on the detected signal 1038 of a change in the first portion 20.1 of the vehicle 12 is comparable to the affect on the detected signal 1038 of a change in the second portion 20.2 of the vehicle 12 for each change corresponding to a relatively similar crash or proximity stimulus or stimuli affecting the first 20.1 and at least second 20.2 portions of the vehicle 12.

Referring to FIGS. 99 a, 99 b, 100 a and 100 b, in accordance with an eighth aspect 10.8 of a magnetic sensor 10, at least one relatively larger coil element L₁′ of the plurality of coil elements 14 at least partially surrounds at least another relatively smaller coil element L₂′ of the plurality of coil elements, wherein both the relatively larger coil element L₁′ and the relatively smaller coil element L₂′ are associated with the same general sensing region 1016, but each exhibits either a different sensitivity thereto or a different span thereof. For example, referring to FIGS. 99 a and 99 b, in accordance with a first embodiment of the seventh aspect 10.7 of a magnetic sensor 10, a first relatively larger coil element L₁′ surrounds a second relatively smaller coil element L₂′, wherein both coil elements L₁′, L₂′ may be either driven by the same oscillatory or pulsed time-varying signal source 201020; or by different oscillatory or pulsed time-varying signal sources 20, each providing either the same or different time-varying signals 24, wherein different time-varying signals 24 could differ by signal type, e.g. oscillatory or pulsed, waveform shape, oscillation frequency or pulsewidth, signal level or power level. The numbers of turns of the coil elements L₁′, L₂′, or the associated heights thereof, can be the same or different as necessary to adapt the relative sensitivity of the relatively larger coil element L₁′ in relation to the relatively smaller coil element L₂′ responsive to particular features of a particular magnetic-field-influencing object 1064 being sensed. For example, the relatively larger coil element L₁′ could have either the same, a greater number, or a lesser number of turns relative to the relatively smaller coil element L₂′, or the relatively larger coil element L₁′ could have either the same, a greater, or a lesser height than the relatively smaller coil element L₂′. Referring to FIGS. 99 a and 99 b, the relatively larger coil element L₁′ and the relatively smaller coil element L₂′ are adapted to sense the inside of a door 78 of the vehicle 12, and are substantially concentric with the associated respective centers 1122, 1124 being substantially aligned with an associated door beam 92 constituting a substantial magnetic-field-influencing object 1064 to be sensed, wherein the relatively smaller coil element L₂′ would be relatively more sensitive to the door beam 92 than the relatively larger coil element L₁′, the latter of which would also be responsive to relatively upper and lower regions of the associated outer skin 90 of the door 78.

Referring to FIGS. 100 a and 100 b, in accordance with a second embodiment of the eighth aspect 10.8 of the magnetic sensor 10, the center 1122 of the relatively larger coil element L₁′ is located below the center 1124 of the relatively smaller coil element L₂′, the latter of which is substantially aligned with the door beam 92, so that the sensing region 1016 of the relatively larger coil element L₁′ is biased towards the lower portion 78′ of the door 78. Accordingly, the relative position of the relatively larger coil element L₁′ in relation to the relatively smaller coil element L₂′ can be adapted to enhance or reduce the associated sensitivity thereof to the magnetic-field-influencing object 1064 being sensed, or to portions thereof.

Referring to FIGS. 101 and 102, in accordance with an embodiment of a ninth aspect 10.9 of the magnetic sensor 10, the magnetic sensor 10 comprises first L₁′ and second L₂′ coil elements relatively fixed with respect to one another and packaged together in a sensor assembly 1132 adapted to be mounted on an edge 118 of a door 78 so that the first coil element L₁′ faces the interior 1136 of the door 78, and the second coil element L₂′ faces the exterior 1138 of the door 78 towards the proximate gap 48, 178 between the edge 118 of the door 78 and an adjacent pillar 184, 174, 175, e.g. a B-pillar 174 for a sensor assembly 1132 adapted to cooperate with a front door 78.1. For example, in the embodiment illustrated in FIG. 101, the sensor assembly 1132 is mounted proximate to the striker 170 on a rear edge 118.1 of the door 78, so as to be responsive to distributed loads from the door beam 92, wherein the front edge 118.2 of the door 78 attached to the A-pillar 184 with associated hinges 176. The first L₁′ and second L₂′ coil elements can be substantially magnetically isolated from one another with a conductive and/or ferrous shield 1148 therebetween, e.g. a steel plate. The first coil element L₁′ is responsive to a deformation of the door 78 affecting the interior 1136 thereof, e.g. responsive to a crash involving the door 78, whereas the second coil element L₂′ is responsive to changes in the proximate gap 48, 178 between the door 78 and the proximate pillar 184, 174, 175, e.g. responsive to an opening or deformation condition of the door 78. Accordingly, the sensor assembly 1132 mounted so as to straddle an edge 118 of the door 78 provides for measuring several distinct features associated with crash dynamics. The sensor assembly 1132 could be mounted on any edge 118 of the door 78, e.g. edges 134.2, 134.1 facing the A-pillar 184, B-pillar 174 or on the bottom edge 118.3 of the door 78, wherein, for example, the position, size, coil parameters, frequency or pulsewidth of the associated at least one time-varying signal 1024, and power thereof, so as to provide for optimizing the discrimination of a crash from associated detected signal or signals 38, or associated components thereof, associated with the first L₁′ and second L₂′ coil elements responsive to deformation of the door 78 and changes in the associated proximate gap or gaps 48, 178. The sensor assembly 1132 can further incorporate an electronic control unit (ECU) 120 incorporating the associated signal conditioner and preprocessor circuits 114 and an associated detection circuit 32, processor 204 and controller 1040. The magnetic sensor 10 can be adapted as a self contained satellite utilizing associated shared electronics, or can incorporated shared connectors and mechanical mounting. The associated detected signal or signals 38, or associated components thereof, associated with the first L₁′ and second L₂′ coil elements can be either used together for crash discrimination, or can be used for combined self-safing and crash discrimination.

Referring to FIG. 103, in accordance with an embodiment of a tenth aspect 10.10 of a magnetic sensor 10, a plurality of coil elements 14, e.g. in a distributed coil 124, together with an associated electronic control unit (ECU) 120, are operatively associated with one or more side-impact air bag inflator modules 1152, for example, mounted together therewith, in a safety restraint system 1154 comprising a combined side crash sensing and side-impact air bag inflator module 1156 so as to provide for a combined side impact crash sensor, one or more gas generators 1158, and one or more associated air bags 1160, in a single package. The combined side crash sensing and side-impact air bag inflator module 1156 could be placed on or proximate to an interior surface 1162 of a door 78, so as to provide for interior deployment of the associated one or more air bags 1160 responsive to the sensing of a crash with the associated magnetic sensor 10 responsive to the influence of a deformation of the door 78 on the associated plurality of coil elements 14 as detected by the associated detection circuit 32 in the electronic control unit (ECU) 120, and the associated generation of a control signal thereby to control the actuation of the associated one or more gas generators 1158 in the associated one or more side-impact air bag inflator modules 1152. For example, the side-impact air bag inflator modules 1152 incorporated in the safety restraint system 1154 illustrated in FIG. 103 comprise a first side-impact air bag inflator module 1152.1 adapted for thorax protection, and a second side-impact air bag inflator module 1152.2 adapted for head protection.

Referring to FIG. 104, the above described magnetic sensor 10 can be adapted for various sensing applications in a vehicle 12. For example, in one set of embodiments, a plurality of coil elements 14 are adapted so as to provide for sensing a deformation of a body portion 1164 of the vehicle 12, for example, a door 78, a quarter-panel 1166, a hood 1168, a roof 1170, a trunk 1172, or a bumper 1174 of the vehicle 12, wherein, for example, the associated plurality of coil elements 14, e.g. distributed coil 124, would be operatively coupled to either a proximate inner panel 84 or structural member 1178 so as to be relatively fixed with respect to the associated deforming body portion 1164 during the early phase of an associated event causing the associated deformation, e.g. an associated crash or roll-over event. In accordance with another set of embodiments, the plurality of coil elements 14, e.g. distributed coil 124, may be mounted inside the door 78 of the vehicle 12 and adapted to provide for detecting a deformation of an associated door beam 92. In accordance with yet another set of embodiments, the plurality of coil elements 14 are adapted so as to provide for detecting a proximity of a second vehicle 1180 relative to the vehicle 12, for example, the proximity of a second vehicle 1180.1 traveling in or from an adjacent lane near or towards the vehicle 12, or a second vehicle 1180.2 traveling along a path intersecting that of the vehicle 12 towards an impending side impact therewith. For example, the associated plurality of coil elements 14, e.g. distributed coil 124, of the magnetic sensor 10 may be integrated into a trim or gasket portion 1182 of the vehicle 12, for example either a door trim portion 1182.1, a body trim portion 1182.2, or an interior trim portion 1182.3. In each of these applications, the associated assembly of the associated plurality of coil elements 14, e.g. distributed coil 124, may be integrated with, into, or on an existing component of the vehicle 12 having a different primary function. The plurality of coil elements 14, e.g. distributed coil 124, can provide for a relatively broad sensing region 1016 using a single associated distributed coil 124 assembly.

It should be appreciated that in any of the above magnetic crash sensor embodiments, that the circuitry and processes associated with FIGS. 35-86 may be used with the associated coil, coils or coil elements 14 so a to provide for generating the associated magnetic field or fields and for detecting the associated signal or signals responsive thereto, as appropriate in accordance with the teachings of FIGS. 35-86 and the associated disclosure hereinabove.

Referring to FIG. 105, a magnetic sensor 2010 is incorporated in a vehicle 12 shown schematically comprising a door 78 that hinges with respect to a first pillar 2016 about a plurality of hinges 2018. The door 78 has a latch/lock mechanism 172′ that latches to a striker 170 on a second pillar 2024.

The door 78—typically constructed with magnetically-permeable steel—has intrinsic magnetic properties. For example, the door 78 conducts magnetic flux, thereby enabling a permanent magnet to stick thereto. The hinges 2018 provide a relatively low reluctance path between the door 78 and the first pillar 2016. Moreover, the latch/lock mechanism 172′ and the striker 170, when engaged, provide a relatively low reluctance path between the door 78 and the second pillar 2024. Elsewhere, the door 78 is normally magnetically separated from the body 168 of the vehicle 12 by an associated air gap 2028. Accordingly, the hinges 2018 and striker 170 are magnetically connected by a first magnetic path 2030 along the door 78. Moreover, the first 2016 and second 2024 pillars—to which the hinges 2018 and striker 170 are respectively attached—are magnetically connected by a second magnetic path 2032—distinct from the first magnetic path 2030—comprising the body 168, structure 2034, or powertrain 2036 of the vehicle 12. Accordingly, the door 78 is part of a magnetic circuit 188 that is similar in nature to the core of a transformer, as illustrated in FIG. 105, wherein the first 2030 and second 2032 magnetic paths together constitute a closed magnetic path 2040.

The magnetic circuit 188 further comprises at least one first coil 2042 operatively connected to at least one first signal 2044, for example an oscillatory signal from an oscillator 2046. The at least one first coil 2042 is located at an associated at least one first location 2048, and responsive to the at least one first signal 2044 generates a magnetomotive force in the magnetic circuit 188 so as to generate a magnetic flux 186 therein. At least one magnetic sensing element 2050 is operatively connected to the magnetic circuit 188 at an associated at least one second location 2052 that is distinct from the at least one first location 2048. The at least one magnetic sensing element 2050 senses the magnetic flux 186, which is responsive to the magnetomotive force from the at least one first coil 2042 and to the magnetic properties of the magnetic circuit 188.

For example, as illustrated in FIG. 105, in a first embodiment, the at least one first coil 2042 may comprise a plurality of first coils 2042.1, 2042.2 at distinct first locations 2048.1, 2048.2, for example operatively coupled with uniform phasing to the top 2018.1 and bottom 2018.2 hinges that operatively couple the door 78 to the “A” pillar 184. Furthermore, each first coil 2042.1, 42.2 may be placed around the associated hinge 2018.1, 2018.2 or around one or more associated mounting bolts that attach the hinge to the first pillar 2016 or to the door 78; and the magnetic sensing element 2050 may comprise a second coil 2054 around the latch/lock mechanism 172′, around the bolts that attach the latch/lock mechanism 172′ to the door 78, or around the striker 170; the associated magnetic circuit 188 thereby forming a transformer with two primary windings comprising the first coils 2042.1, 2042.2; a secondary winding comprising the second coil 2054; and a core comprising the first pillar 2016, the hinges 2018.1, 18.2, the door 78, the second pillar 2024, the air gap 2028 around the door 78, and the remainder of the body 168, the structure 2034 and the powertrain 2036 of the vehicle 12. Stated in another way, the first embodiment comprises a transformer with three coils, two of them active and one of them passive.

The first signal 2044 comprises a sinusoidal voltage generated by an oscillator 2046 comprising a crystal stabilized (i.e. substantially drift-free) TTL square wave signal generated by a microprocessor 2056 and subsequently filtered by a band-pass filter. The signal from the oscillator 2046 is fed to a coil driver 2058—for example, through a buffer amplifier.

The oscillation frequency of the oscillator 2046 is selected, as a function of the expected noise sources, to enhance system performance. For example, a frequency different from that of AC power lines (e.g. 60 Hz) could be chosen to avoid interference therefrom. Ultrasonic frequencies appear to be useful. The permeability of typical automotive steel is frequency dependent with a bandwidth of about 100 KHz. The frequency range of the permeability of the associated magnetic circuit 188 can likely be extended to 1 MHz or higher by adding materials such as ferrite or mu-metal thereto.

The skin depth of the magnetic flux 186 is responsive to frequency, so the depth of the magnetic flux 186 in the door 78 and the shape and reach of the associated proximity field can be varied by changing the oscillation frequency (or frequencies). The oscillator 2046 may be modulated either in amplitude, frequency, or by bursting.

Each at least one first coil 2042 is driven by an associated coil driver 2058 that provides sufficient power at an impedance compatible with the first coil 2042 so that the resulting magnetic flux 186 is sufficiently strong to be detected by the at least one magnetic sensing element 2050. The coil driver 2058 is also, for example, provided with short circuit protection and is operated so as to avoid saturation or clipping of the first signal 2044. The coil driver 2058 is designed to operate in an automotive environment, for example to operate over a associated range of possible battery voltages. The first signal 2044 from the coil driver 2058 may, for example, be either a voltage signal or a current signal.

The coil driver 2058 drives the first coil 2042 through a sense/test circuit 2060. The sense/test circuit 2060 senses either a current or voltage from the first coil 2042, or a signal from a supplemental sense coil 2062, or a combination of the three, to confirm or test the operation of the first coil 2042. This also provides a continuous test of the integrity of the door 78. For example, a supplemental sense coil 2062 would directly sense the magnetic flux 186 generated by the first coil 2042. The sense/test circuit 2060 may also, for example, test the first coil 2042 for an open or short so as to improve the reliability of the magnetic sensor 2010, particularly when used to control the actuation of a safety restraint actuator 110, so as to prevent a false deployment or a failure to deploy when necessary. The integrity, or health, of the at least one first coil 2042 is, for example, tested every measurement cycle.

A plurality of first coils 2042 may be driven separately, as illustrated in FIG. 105, or connected in series or parallel and driven by a common coil driver 2058. The at least one first coil 2042 may, for example, be series resonated to increase the current flow therein, thereby increasing the amount of magnetic flux 186 generated by the at least one first coil 2042, and the amount of magnetic flux 186 induced in the magnetic circuit 188. This also increases the magnitude and extent to the leakage field proximate to the air gap(s) 2028 of the magnetic circuit 188, thereby extending the range of associated proximity sensing by the magnetic sensor 2010. Increased magnetic flux 186 in the magnetic circuit 188 provides for a higher signal-to-noise ratio in the signal or signals received or detected by the magnetic sensor 2010. When in series resonance, the inductive reactance of the first coil 2042 is canceled by an associated capacitive reactance, so that the resulting total impedance is purely resistive, so that a given operating voltage can be accommodated, or an associated Q of the resonant circuit can be adjusted, either by adjusting the resistance of an associated series resistor or by adjusting the inherent resistance of the first coil 2042 (e.g. by adjusting either the size or length, or both, of the conductor thereof). The at least one first coil 2042 may be compensated for variations in temperature by incorporating an associated temperature sensor. For a coil mounted around a hinge 2018 on the “A” pillar 184, the body metal would act as a heat sink to help maintain the temperature of the first coil 2042 near ambient temperature.

The sense/test circuit 2060 also provides a measure of the power delivered to the first coil 2042 so that the magnetic flux 186 coupled to proximate metal objects can be estimated. For example, a steel object such as another vehicle proximate to the door 78 provides an alternate path for magnetic flux 186 from the at least one first coil 2042, which affects the magnetic circuit 188 and the reluctance seen by the at least one first coil 2042, thereby changing the load on the at least one first coil 2042, which changes the power provided thereto by the coil driver 2058. Generally, a portion of the magnetic flux 186 generated by the at least one first coil 2042 is coupled within the magnetic circuit 188, and a portion bypasses the magnetic circuit 188, whether via an alternate magnetic path or by radiation. The portion of magnetic flux 186 that bypasses the magnetic circuit 188 increases the load upon the coil driver 2058, which increase is sensed by a bypass power processor 2066 using measurements from the sense/test circuit 2060 of the voltage across and the current through the at least one first coil 2042. For a plurality of first coils 2042, the bypass power processor 2066 can provide a measure of direction to a proximate magnetic-field-affecting object from the separate measurements of the associated separate sense/test circuits 2060.1 and 2060.2, particularly from a measure of the difference in currents flowing to the separate first coils 2042.1 and 2042.2 for a given common drive voltage.

The at least one magnetic sensing element 2050 is responsive to the magnetic flux 186 at the second location 2052, including both a first portion of magnetic flux 186 that is conducted through the door 78, and a second portion of magnetic flux 186, i.e. leakage flux, that bypasses at least a portion of the door 78—for example as a result of an object, such as another vehicle proximate to the door 78, that couples magnetic flux 186 from the at least one first coil 2042 to the at least one magnetic sensing element 2050.

An output from the at least one magnetic sensing element 2050 is operatively connected to a preamplifier/test circuit 2068 which, for example, buffers the magnetic sensing element 2050 from loading by the subsequent circuitry and provides a relatively low impedance output so as to reduce noise. The preamplifier/test circuit 2068 also amplifies the signal from the at least one magnetic sensing element 2050 to a level sufficiently high to permit appropriate signal processing and demodulation before subsequent analog-to-digital conversion for processing by the microprocessor 2056. The microprocessor 2056 gathers data, monitors system health and integrity, and determines whether or not to actuate the safety restraint actuator 110.

The preamplifier/test circuit 2068 also monitors the integrity of the magnetic sensing element 2050, for example by comparing the signal therefrom with “expected” levels and expected wave shapes (e.g. a sinusoidal shape). This provides a continuous test of the integrity of the magnetic sensing element 2050 and the magnetic transfer function property of the door 78. The preamplifier/test circuit 2068 may also, for example, test the at least one magnetic sensing element 2050, for example a second coil 2054, for an open or short so as to improve the reliability of the magnetic sensor 2010, particularly when used to control the actuation of a safety restraint actuator 110, so as to prevent a false deployment or a failure to deploy when necessary. The integrity, or health, of the at least one magnetic sensing element 2050 is tested every measurement cycle.

The magnetic sensing element 2050 senses from the magnetic flux 186 proximate thereto a sinusoidal carrier that is modulated responsive to the reluctance of the magnetic circuit 188. This signal from the magnetic sensing element 2050 is amplified by the preamplifier/test circuit 2068, and a synchronous demodulator 2070 operatively connected thereto extracts the modulation signal from the sinusoidal carrier, which modulation signal contains a bent metal signal component 2072 and a proximity signal component 2074. The bent metal signal component 2072 is responsive to the magnetic flux 186 conducted through the metal of the door 78. The proximity signal component 2074 is responsive to the leakage magnetic flux 186 that is coupled between the at least one first coil 2042 and the magnetic sensing element 2050 along a path that bypasses the metal of the door 78. The difference in the relative strengths of the bent metal signal component 2072 and a proximity signal component 2074 is dependent upon the difference in permeances of the associated magnetic flux paths.

A bent metal processor 2076 DC couples—with, for example, unity gain—the bent metal signal component 2072 to the microprocessor 2056 through an A/D converter 2078.1. The bent metal signal component 2072 is responsive to the time rate of change of magnetic flux 186 in the door 78. Relatively slow signals of relatively low amplitude correspond to non-deployment events for which a safety restraint actuator 110 should not be deployed, for example a low speed impact of the door 78 by a shopping cart. Relatively fast signals of relatively large amplitude correspond to deployment events for which a safety restraint actuator 110 should be deployed, for example an impact of the door 78 by a pole or barrier (e.g. an FMVSS-214 condition). During a pole crash, the steel of the door 78 becomes magnetically shorted to the adjacent body, thereby magnetically shorting the flux path—as a result of either the magnetic influence of a proximate magnetic object (e.g. a steel pole), or by the physical affect of the impact on the associated magnetic circuit 188—which significantly reduces the magnetic flux 186 sensed by a magnetic sensing element 2050 at the striker 170. The magnetic sensing element 2050 is responsive to those changes to the magnetic circuit 188 which either increase or decrease the associated magnetic flux 186 sensed thereby.

The proximity processor 2080 amplifies the proximity signal component 2074 from the synchronous demodulator 2070 by some gain factor based on coil geometry and vehicle structure, and DC couples the amplified signal through an A/D converter 2078.2. The proximity signal component 2074 is responsive to the time rate of change of magnetic flux 186 that bypasses door 78. Notwithstanding a greater susceptibility to noise in comparison with the bent metal signal component 2072, the proximity signal component 2074 enables the detection of metallic (particularly ferromagnetic) objects that are approaching the door 78, for example a vehicle approaching at high speed or a vehicle in an adjacent lane of traffic. Another vehicle approaching the door 78 on a collision course therewith is indicated by a relatively fast signal, for which a safety restraint actuator 110 would be deployed upon impact if followed by a corresponding bent metal signal component 2072.

Accordingly, if the rate of change of the proximity signal component 2074 is greater than a first threshold, then the safety restraint actuator 110 is deployed when the bent metal signal component 2072 exceeds a second threshold and the rate of change thereof exceeds a third threshold. Otherwise, if no bent metal signature follows, for example if the proximity signal component 2074 had resulted from a passing vehicle, then the system stands down.

The above described magnetic sensor 2010 can be embodied in various ways. The particular circuitry, whether analog, digital or optical is not considered to be limiting and can be designed by one of ordinary skill in the art in accordance with the teachings herein. For example, where used, an oscillator, amplifier, logic element, modulator, demodulator, A/D converter can be of any known type, for example using transistors, for example field effect or bipolar, or other discrete components; integrated circuits; operational amplifiers, or logic circuits, or custom integrated circuits. Moreover, where used, a microprocessor can be any computing device.

In accordance with the theory of magnetic circuits and transformers, magnetic lines of flux always close on themselves and preferably follow a path of least magnetic resistance, for example so as to follow the path of ferromagnetic materials, such as steel or ferrite materials. Moreover, changes in area or permeability along the magnetic circuit cause a leakage of magnetic flux 186 proximate thereto, which leakage is also known as fringing. A magnetic circuit 188 is characterized by a reluctance

, wherein the amount of magnetic flux φ in a magnetic circuit for a given magnetomotive force F is given by φ=F/

. The reluctance

of a series magnetic circuit is given by the sum of the respective reluctances of the respective elements in series. The reluctance of an air gap is significantly greater than that of a ferromagnetic material, and as a result, the magnetic flux leaks into the space surrounding the air gap, forming a leakage field. A ferromagnetic object entering the leakage field provides an alternate path for the magnetic flux, thereby bypassing the air gap and affecting the reluctance of the magnetic circuit 188. Stated in another way, the leakage flux field changes shape so that the ferromagnetic object becomes part of the magnetic circuit 188.

As illustrated in FIG. 105, a door 78 can be modeled as an element of a closed magnetic circuit 188 that is similar to a transformer core. The fore and aft ends of the door 78 are magnetically connected in series with the remainder of the magnetic circuit 188 by the hinges 2018 and the coupling of the latch/lock mechanism 172′ to the striker 170. The remainder of the door 78 is magnetically insulated from remainder of the magnetic circuit 188 by an air gap 2028 that otherwise surrounds the door 78.

A first coil 2042 has a self-inductance which has one value when the first coil is in free space, and another when the coil is operatively connected to a magnetic circuit 188, for example by wrapping the first coil 2042 around a portion of the magnetic circuit 188. In the latter case, the self inductance of the first coil 2042 is dependent upon the magnetic properties of the magnetic circuit 188. Moreover, the magnetic properties of the magnetic circuit 188 are altered if the magnetic circuit 188 is physically deformed, or if ferromagnetic elements are brought in proximity with the magnetic circuit 188, particularly in proximity with the leakage fields thereof. Accordingly, a deformation of the door 78 or the approach of another vehicle to the door 78 are both examples of perturbations to the magnetic properties of the magnetic circuit 188, both of which can be detected by either a change in inductance of the first coil 2042, or by a change in the magnetic coupling between a first coil 2042 at a first location 2048 and a magnetic sensing element 2050 for sensing the magnetic flux 186 in the magnetic circuit 188 at a second location 2052 distinct from the first location 2048.

In operation, the at least one first signal 2044 operatively coupled to the associated at least one first coil 2042 by the associated at least one coil driver 2058 causes a current flow in the at least one first coil 2042 which generates a magnetic flux 186 therein, which in turn generates a magnetic flux 186 in the magnetic circuit 188 to which the at least one first coil 2042 is coupled. The magnetic flux 186 is conducted by the door 78, which is a part of the magnetic circuit 188. The at least one first signal 2044 comprising an oscillating signal, for example a sinusoidal voltage or current excitation, is applied to at least one first coil 2042 operatively coupled to a hinge 2018 of a door 78. Referring to FIGS. 106 a and 106 b, the at least one first coil 2042 converts the at least one first signal 2044 into magnetic flux 186, which is then induced in the magnetic circuit 188 by virtue of the at least one first coil 2042. The magnetic flux 186 comprises a plurality of magnetic flux lines 2084, some of which may leak out beyond the physical boundary of the magnetic circuit 188, particularly at locations proximate to air gaps 2028 in the magnetic circuit 188. The magnetic flux lines 2084 follow steel and other ferromagnetic elements of the door 78 that attract magnetic flux 186 therein in relation to the permeance thereof in comparison with the substantially lower permeance of the surrounding air.

The at least one first signal 2044 from the oscillator 2046 is amplified by the associated at least one coil driver 2058 and operatively coupled to the at least one first coil 2042 through an associated sense/test circuit 2060. The at least one first coil 2042 generates a magnetic flux 186 in the magnetic circuit 188, particularly the door 78, and at least a portion of the magnetic flux 186 is sensed by the magnetic sensing element 2050, for example by a second coil 2054 wrapped around the striker 170.

The magnetic flux 186 travels through the magnetic circuit 188, particularly the ferromagnetic portions thereof including those of the portions of the vehicle 12, such as the door 78, that are monitored by the magnetic sensor 2010. A first portion 2086 of the magnetic flux 186, known herein as the bent metal flux component 2086, passes through the ferromagnetic elements of the magnetic circuit 188 and is sensed by the magnetic sensing element 2050, which provides a first signal component 72 known herein as a bent metal signal component 2072 that is responsive thereto, or in other words, that is responsive to changes of the magnetic characteristics of the magnetic circuit 188. The magnetic flux 186 seeks to travel inside the steel structure of the door 78. More magnetic flux 186 automatically enters those parts of the steel that are thicker, which would likely correspond to those elements of the door structure that add strength to the door 78. Where the steel is thinner, the magnetic flux density is correspondingly reduced. Stated in another way, the magnetic flux 186 travels in ratiometric proportion with the cross-sectional area of the steel. The magnetic flux 186 is generally not present in the plastic parts other than as a result of leakage elsewhere in the magnetic circuit 188, however, for a steel door 78, these parts are generally not structural. Accordingly, the magnetic sensor 2010 generates magnetic flux 186 that passes through the structural elements of the door 78, and is responsive to mechanical changes to these structural elements to a degree that those mechanical changes influence the magnetic flux 186.

A second portion 2088 of the magnetic flux 186, known herein as the proximity flux component 2088, extends outside the physical extent of the magnetic circuit 188 and is sensed by the magnetic sensing element 2050, which provides a second signal component 2074 known herein as a proximity signal component 2074 that is responsive thereto, or in other words, that is responsive to changes of the magnetic characteristics of a region proximate to the magnetic circuit 188.

Changes to the size, shape, position, construction integrity, spot-weld quantity and integrity, material correctness, and assembly alignment of the door 78; or to the magnetic environment proximate to the door 78, for example, by the presence of a ferromagnetic object such as another vehicle 2090; affect the magnetic circuit 188, and thereby affect magnetic flux 186 sensed by the magnetic sensing element 2050.

The door 78, or another part of the magnetic circuit 188 subject to surveillance, may be supplemented or modified by adding or relocating steel or other highly permeable material in the door 78 to as to modify the strength and/or shape of the respective first 2086 and second 2088 portions of the magnetic flux 186, thereby enhancing the associated magnetic circuit 188 so as to improve the respective bent metal 2072 and/or proximity 2074 signal components. This may further enable a reduction in power to at least one coil driver 2058, thereby reducing associated radiated power from the at least one first coil 2042. Moreover, this may enable a reduction in gain of the associated preamplifier/test circuit 2068, which improves the associated signal-to-noise ratio. The magnetic flux 186 generally follows a path of least reluctance, which typically would correspond to sections of greatest amounts of magnetically permeable material. For a door 78 constructed of steel, this path would then correspond to one or more sections of the door 78 that contribute substantially to the strength of the door 78. Accordingly, the magnetic circuit 188 can be optimized with respect to magnetic performance, strength and cost by this supplementation or modification of the associated magnetically permeable material.

For example, the magnetic circuit 188 can be modified or augmented in various ways, including but not limited to the following, many of which provide for increasing the ratio of magnetic flux density per unit drive current and thereby increase the magnetic efficiency of the magnetic circuit 188:

-   -   1. Mu-metal, ferrite or some other magnetic conductor can be         added to the door 78, for example to a plastic door 78, e.g. by         coating the inside of the door 14 with a ferrite paint or         coating to increase the permeability thereof, to augment or         re-tune the door's natural magnetic characteristic;     -   2. Holes may be added to the door 78 or modified, thus shifting         the magnetic conduction;     -   3. A supplemental ferrite or mu-metal flexible linkage may be         added between the “A” pillar 184 and the door 78 for generating         the magnetic flux 186, instead of the hinges 2018;     -   4. Ferrite, an amorphous metal (e.g. METGLAS®), or mu-metal may         be placed in the striker 170 and second coil 2054, or generally         added to or used as the core of either the first 2042 or second         2054 coil to enhance the magnetic flux 186 therein, or to         provide for operating at a lower current level for the same         amount of magnetic flux 186;     -   5. A permanent magnet may be added to the door 78 to augment or         re-tune the intrinsic permanent magnetic characteristic signal         of the magnetic circuit 188;     -   6. The magnetic structure of the door 78 can be changed, for         example by using a thinner metal skin, a plastic door skin, or         ferrite rods to change the magnetic gain, so as to enhance         proximity sensing for enhanced system safing responsive to the         proximity flux component 2088;     -   7. The hinge or striker shape, size, or material can be changed         to improve their associated magnetic characteristics; and     -   8. The door side-guardrail assembly and construction, the hinge         assembly, or the latch/lock mechanism/striker assembly can be         changed to enhance system performance and sensitivity.

In addition to the herein described use in detecting a crash or an impending crash, the magnetic sensor 2010 can also be used to monitor the structural integrity of structural elements of the magnetic circuit 188, particularly the structural integrity of the door 78, for example as a post manufacturing inspection of a door 78 either mounted to a vehicle 12, or separate therefrom in a magnetic circuit of an associated test apparatus. For example, a missing structural element, such as guard rail, or poor spot welds, would likely affect the reluctance of the door 78 and if so, could be detected prior to assembly. Stated another way, a steel door 78 that does not conduct magnetic flux 186 well would not likely have sufficient side-impact strength. Accordingly, the door 78 can be tested for proper magnetic integrity, which can be predictive of the performance of the magnetic sensor 2010, and indicative of the ability of the door 78 to withstand impact and thereby protect an occupant therefrom.

The magnetic sensing element 2050 is responsive to a superposition of the first 2086 and second 2088 portions of magnetic flux 186, and converts the composite of both portions to a voltage that is amplified by the preamplifier/test circuit 2068, wherein the relative strengths of the associated bent metal 2072 and proximity 2074 signal components is in proportion to the associated relative strengths of the first 2086 and second 2088 portions of magnetic flux 186. The magnetic sensing element 2050 may be Faraday shielded to reduce noise, wherein a Faraday shield would shield the magnetic sensing element 2050, e.g. second coil 2054, from stray electric fields so as to prevent or reduce noise in the signal therefrom. For a magnetic sensing element 2050 comprising a second coil 2054, for example around the striker 170, the second coil 2054 may be also be parallel resonated to match the associated carrier frequency of the at least one first signal 2044 so as to improve the associated signal-to-noise ratio. Parallel resonance of the second coil 2054 provides for increasing the strength of the signal therefrom, and for increasing the sensitivity thereof to variations in the magnetic flux 186 in the magnetic circuit 188. Experiments have shown that locating the second coil 2054 proximate to the end wall 2092 of the door 78 enhances the awareness of the proximity flux component 2088 of the magnetic flux 186. This suggests that the latch/lock mechanism 172′—a localized thickening of the door metal—may act be as a magnetic lens to magnify the effect of the proximity flux component 2088 at the second coil 2054. The air gap 2028 helps to create the proximity flux component 2088, and the region of greatest sensitivity by the proximity flux component 2088 to approaching objects is proximate to the air gap 2028. Impacts to the door 78 tend to modulate the air gap 2028, causing significant changes to the associated magnetic flux lines 2084, thereby causing the magnetic sensing element 2050 to generate an associated signal of significant magnitude. The signal responsive to the modulated air gap 2028 provides a measure of instantaneous recoil velocity of the door 78, which may be used to detect door bounce events for which an associated safety restraint actuator 110 is typically not deployed. The magnetic sensor 2010 can be responsive to movement of a latched door 78,

More particularly, the door 78 acts as a rigid body at the beginning of a collision and is pushed inwards towards the body of the vehicle 12 against the compliance of the weatherseal surrounding the door 78, thereby exhibiting elastic behavior. The magnetic flux 186 sensed by the magnetic sensing element 2050 changes responsive to the movement of the door 78, thereby enabling the lateral position and velocity of the door 78 to be measured from that change.

If the momentum of the impact is less than a threshold, for example for small objects or low impact velocities, the door 78 will then bottom out within a range of elastic behavior and rebound, thereby reversing the above described change to the magnetic flux 186 which is indicated by a shift in polarity of the signal from the magnetic sensing element 2050. Accordingly, the detection of such a rebound event is indicative of an impact for which the safety restraint actuator 110 would not be necessary. Otherwise, if the momentum of the impact is greater than a threshold, then the door 78 becomes plastically deformed, resulting in a significant change to the bent metal signal component 2072, which can be indicative of a need to subsequently deploy the safety restraint actuator 110. Accordingly, if after an initial movement of the door 78 is detected, either the door 78 fails to rebound and/or a significant bent metal signal component 2072 is detected, then the impact might be considered to be sufficiently severe to warrant the deployment of the safety restraint actuator 110. Moreover, the initial velocity of the door 78 can be used as a predictor or indicator of impact severity.

A ferromagnetic door 78 is characterized by an associated natural permanent magnetic field which acts to generate a static magnetic flux 186 within the magnetic circuit 188 responsive to the reluctance of the magnetic circuit 188, changes to which as a result of door motion are sensed by the magnetic sensing element 2050. This response—effectively an AC transformer transfer component—is superimposed upon the response to the at least one first signal 2044, and can provide an independent measure of door motion and impact velocity.

Experiments have shown that responsive to an FMVSS-214 impact the door 78 can rotate about its centerline causing—at the beginning of the impact—an increase in the air gap 2028 between the door 78 and the vehicle body at the top of the door 78. By comparison, experiments have shown that a pole-type impact causes a corresponding reduction in the air gap 2028. Accordingly, the behavior of the air gap 2028 responsive to a crash can be used to identify the type of crash. Accordingly both the type and severity of the crash can be detected by the magnetic sensor 2010. Commencing with an impact, the door 78 is generally moves readily responsive to the crash until the latch/lock mechanism 172′ bottoms out against the associated striker 170. Accordingly for a striking object that is relatively massive in comparison with the door 78, the velocity of impact can be measured by the magnetic sensor 2010 from the motion of the door 78 prior to this “bottoming out” thereof. After the door 78 “bottoms out” against the vehicle body, the impact causes bending or deformation of the door 78, causing further changes to the magnetic circuit 188 that are sensed by the magnetic sensor 2010, providing further information about the intensity and duration of the crash.

Another vehicle 2090 proximate to the at least one first coil 2042 attracts magnetic flux 186, thereby causing a third portion 2094 of the magnetic flux 186 generated by the at least one first coil 2042 to bypass the magnetic sensing element 2050. Moreover, if the door 78 becomes dented or deformed, the distribution and/or strength of the magnetic flux 186 in the door 78 changes, which change is sensed either by the magnetic sensing element 2050 or by a change in the load upon the at least one first signal 2044 by the at least one first coil 2042. Accordingly, substantially the entire door 78 acts a sensing element of the magnetic sensor 2010, wherein the effect of changes to the magnetic characteristics thereof on the number and distribution of the magnetic flux lines 2084 propagates at the speed of light from the location of the disturbance to either the at least one first coil 2042 or the magnetic sensing element 2050. Moreover, by placing the at least one first coil 2042 on at least one hinge 2018, and the second coil 2054 on the striker 170, the door 78 becomes a sensing element without actually running any wires or signal cables into the door 78. The magnetic sensor 2010 using the door 78 as a sensing element in a proximity sensing mode can be used to either monitor a blind spot of the vehicle 12 or to monitor traffic in an adjacent lane. The extent of coverage by the proximity mode can be increased by increasing the strength of the associated magnetic flux 186, e.g. by increasing the current supplied to the first coil 2042, or by adapting the associated magnetic circuit 188 to increase the associated proximity flux component 2088.

With substantially the entire door 78 as a sensor, the magnetic sensor 2010 can sense incoming objects approximately of door dimension. Car bumpers and roadside poles similar to the door dimension, for which a safety restraint actuator 110 would be required in a crash, will generally be visible whereas basketball and other small objects, for which a safety restraint actuator 110 would not be required, would be less visible. A shopping cart loaded with groceries would also be visible to the magnetic sensor 2010, however the decision of whether or not to deploy a safety restraint actuator 110 would be based upon more factors than just the visibility of a particular object. The magnetic sensor 2010 is not responsive to impacts such as impacts to the undercarriage, for example from a rock, that do not affect the magnetic circuit 188, but which might otherwise affect an acceleration based crash sensor.

Accordingly, the magnetic sensor 2010 is responsive to various physical effects upon the magnetic circuit 188, including but not limited to the following:

-   -   1) Changes to the air gap 2028 of the magnetic circuit affecting         the bent metal signal component 2072.     -   2) Changes in the shape and density of the proximity flux         component 2088 proximate to the air gap 2028 surrounding the         door 78, including the front edge of the door 78 and front         fender, the rear edge of door 78 and rear fender (or the rear         door 78 of a four (4) door vehicle), the bottom of the door 78         to floor board, and, to a lesser extent, the top of the door 78         or window frame to the roof. The bent metal signal component         2072 is responsive to deformations of the door 78 or adjacent         body components that close, or short, the air gap 2028.     -   3) The door 78, particularly the skin thereof, has a natural         resonant frequency that can be excited by the at least one first         coil 2042 if driven at that frequency the at least one first         signal 2044. An impact to the door 78 induces vibrations therein         associated with the resonant frequency thereof, and with         associated overtones. At this resonant frequency, if the         vibrating elements of the door 78 become constrained as by         contact with an impacting object, this causes a dampening of the         resonance which increases the eddy current losses in the         magnetic circuit 188, which can be measured by the bypass power         processor 2066 from the power supplied to the at least one first         coil 2042. Furthermore, the impacting object can influence the         associated resonances, so that the nature of the resonances         measured by the magnetic sensor 2010 provides associated         information about the nature of the impact—e.g. severity—or the         nature of the impacting object. Stated in another way, the door         78 has a natural resonant behavior, but exhibits a forced         response to the impact thereof by an impacting object because of         the continued interaction of the impacting object with the door         78.     -   4) The structural elements of the door 78 typically provide a         path of least reluctance for the associated magnetic flux 186,         and mechanical stresses therein can alter the reluctance         thereof, so that changes to the magnetic flux 186 can be related         to the level of forces applied to the door 78 and to the         structural elements thereof, which force levels can be related         to the momentum or velocity of the impacting object.         Accordingly, the measurements of the magnetic flux 186 provides         a measure of threat to the door 78.

The bent metal 2072 and proximity 2074 signal components in the composite signal from the magnetic sensing element 2050 are demodulated by the synchronous demodulator 2070 and amplified by different respective gains of the associated bent metal 2076 and proximity 2080 processors, wherein the respective gains are for example in proportion to the relative permeance of the materials associated with the respective magnetic flux components. The bent metal 2072 and proximity 2074 signal components differ with respect to signal magnitude, and without further differentiation, only one of the two components would be useful at a given time. Prior to impact, the proximity signal component 2074 provides information about a proximate object. However, after the occurrence of an impact, the proximity signal component 2074 becomes relatively small, if not insubstantial, in comparison with the corresponding bent metal signal component 2072. For example, the proximity signal component 2074 might have a magnitude of 0.2 volts, which is about twenty five times smaller than the corresponding bent metal signal component 2072 after impact, which might have a magnitude of 5.0 volts. For example, when the bent metal signal component 2072 is of sufficient magnitude to indicate a physical disturbance of the magnetic circuit 188, then the proximity signal component 2074 would be saturated. Otherwise, the bent metal signal component 2072 would be of negligible magnitude and the proximity signal component 2074 would be useful for detecting objects proximate to the door 78. This mutual exclusive utility of the respective signal components is consistent with the sequence of a crash, in that an impacting object becomes proximate to the vehicle 12 before impacting the door 78; and after the impact has occurred as indicated by the bent metal signal component 2072, there would likely be little need to continue to detect the proximity signal component 2074.

Given the bent metal 2072 and proximity 2074 signal components, the microprocessor 2056 can monitor the total magnetic health of the door 78 and be aware of relatively large metal objects in proximity thereto. An example of one algorithm using this information to control a safety restraint actuator 110 would be to monitor the proximity signal component 2074 to detect a relatively rapid approach of a relatively large metal object. When the proximity signal component 2074 becomes saturated, indicating a likely perturbation to the physical magnetic circuit 188, then if the bent metal signal component 2072 indicates a sufficiently large change, then it is assumed that a potentially injurious impact has occurred and the safety restraint actuator 110 would be actuated. Otherwise, if the proximity signal component 2074 returns to a quiescent state without the occurrence of a significant bent metal signal component 2072, then it is assumed that the door 78 has not been impacted, but instead, for example, another vehicle has passed by the door 78, and the safety restraint actuator 110 would not be actuated.

Both the power applied to the at least one first coil 2042, and the gain and phase of the signal from the magnetic sensing element 2050 in relation to the at least one first signal 2044, are continuously monitored and stored in a memory 2095 of a microprocessor 2056 as a real-time magnetic signature of the door 78. In an embodiment of the magnetic sensor 2010 responsive to relative phase, the phase of the signal from the magnetic sensing element 2050 can be compared with that of the first signal 2044 from the oscillator 2046 with a phase detector 2096 which outputs the associated phase difference to the microprocessor 2056. The real-time magnetic signature is compared with at least one other comparable magnetic signature—for example at least one magnetic signature representing the door 78 prior to an impact or collision, i.e. a normal signature; or at least one magnetic signature representing various impacts or crashes—in order to determine if an associated safety restraint actuator 110 should be actuated. The at least one normal signature may include magnetic signatures that account for variations in the magnetic flux 186 as a result of either metal objects proximate to or approaching the door 78 or variations as a result of corrosion or variations in temperature. The normal signature may be updated over time so as to track minor perturbations of the door 78, such as due to temperature or corrosion, which changes would likely occur relatively slowly over time. If the real-time magnetic signature of the bent metal signal component 2072 is sufficiently different from the normal magnetic signature, the microprocessor 2056 would actuate the safety restraint actuator 110.

Accordingly, the magnetic sensor 2010 is responsive to both small-signal and large-signal disturbances. Small-signal disturbances would include, for example, impacts by relatively small objects such as basketballs or other sporting projectiles, which typically do not cause plastic deformation of the door 78, but for which the door 78 and surrounding weather-seal respond elastically. Large-signal disturbances would include, for example, side impacts that causes plastic deformation of the door 78, thereby permanently shifting its magnetic signature. The magnetic sensor 2010 detects the change in magnetic signature from the pre-impact undeformed condition to the post-impact deformed condition. Moreover, the plastically deformed metal is work hardened which causes a change to the permeance thereof, which is sensed by the magnetic sensor 2010. At the beginning of the impact, prior to plastic deformation of the door 78, the magnetic sensor 2010 is able to estimate the impact velocity and severity of the impact using principles of the physics of collisions including conservation of energy and momentum, whereby the response of the door 78 increases with increasing impact severity. The signal from the magnetic sensing element 2050 comprises information about both the instantaneous position and the instantaneous velocity of the door 78. Moreover, particular polarities of the signal are indicative of particular motions of the door 78.

The magnetic sensor 2010 provides a real-time validation of the health and integrity of the respective at least one first coil 2042 and the second coil 2054, by testing the respective coils for shorts or open conditions, or by using a separate sense coil 2062 to detect the magnetic flux 186 generated by the at least one first coil 2042. Moreover, the magnetic sensor 2010 provides a continuous test of the integrity of the magnetic circuit 188, including the component under magnetic surveillance, for example the door 78.

Referring to FIG. 105, in first alternate embodiment of the magnetic sensor 2010, the at least one first coil 2042 comprises a plurality of first coils 2042.1 and 2042.2 at distinct first locations 2048.1 and 2048.2, for example operatively coupled to the top 2018.1 and bottom 2018.2 hinges that operatively couple the door 78 to the “A” pillar 184. The separate first coils 2042.1 and 2042.2 are driven by separate corresponding first signals 2044.1 and 2044.2, each having a distinct phase with respect to the other, so as to create a magnetic flux 186 that “rotates” while traveling through the door 78 to the magnetic sensing element 2050, whereby an impact to the door 78 affects the trajectory of the separate signals, thereby affecting the relative distribution of the different phases in the signal sensed by the magnetic sensing element 2050. The relative phase of the separate first signals 2044.1 and 2044.2 is controlled by a phase control circuit 2098 between the oscillator 2046 and one of the coil drivers 2058, and which, for example, is under control of the microprocessor 2056. The phase encoding of the respective first signals 2044.1 and 2044.2 is similar in theory to the phase encoding of color television and FM radio signals so as to increase the transfer of information along a channel with limited bandwidth. By separately encoding the separate first signals 2044.1 and 2044.2, these respective signals from the first coils 2042.1 and 2042.2—respectively around the top 2018.1 and bottom 2018.2 hinges—can be distinguished in the signal from the magnetic sensing element 2050 so as to provide a measure of the vertical location of an impact to the door 78.

Referring to FIG. 107, in a second alternate embodiment of the magnetic sensor 2010, the at least one first coil 2042 comprises a first coil 2042 at a first location 2048 and a plurality of magnetic sensing elements 2050, for example second coils 2054.1 and 2054.2 at respective distinct second locations 2052.1 and 2052.2 that are each distinct from the first location 2048. For example, the first location 2048 might be the bottom hinge 2018.2 for improved signal-to-noise ratio, and the second locations 2052.1 and 2052.2 might be the striker 170 and the top hinge 2018.1 respectively. Such an arrangement would exhibit enhanced sensitivity to impacts proximate to the bottom hinge 2018.2.

The at least one first coil 2042 or the at least one magnetic sensing element 2050 can be located at a variety of locations and constructed in accordance with a variety of configurations, including but not limited to the following: one or more hinges; the striker; the side impact protection rail or beam inside the door 78; around or proximate to the latch/lock mechanism either inside or outside the door 78; inside the spot weld line on the top or bottom of the door 78; around or proximate to the hinge bolts; on the inner door skin of a plastic or steel door 78 with the perimeter of the coil nearly matching the perimeter of the door 78; around the window glass perimeter; around the entire door structure such as in the air gap surrounding the door 78 and the opening that one passes through when entering or exiting the vehicle; in a window such as the driver-side window, as a defroster; behind a plastic door handle or trim component, along with associated electronics; around the window glass opening in the door 78 through which the window is lowered; or in the plastic side view mirror housing for sensing over an extended range, for example to locate steel objects that might pose a side-impact threat.

The magnetic fields generated by these arrangements have a variety of principal orientations, including but not limited to longitudinal, transverse, and vertical. For example, a first coil 2042 can be placed around a hinge 2018 so that the associated magnetic field is either longitudinal or transverse, the former arrangement providing principally a bent metal flux component 2086, whereas the later arrangement providing a relatively strong proximity flux component 2088. As another example, a first coil 2042 around the window glass opening in the door 78 through which the window is lowered generates a vertical magnetic field that circulates around the vehicle along a transverse section thereof. As yet another example, a first coil 2042 around the door 78 or window in the plane thereof generates a transverse magnetic field that is useful for proximity sensing. Different first coils 2042, at least one adapted to produce principally a bent metal flux component 2086 and the other adapted to produce principally a proximity flux component 2088 can be used with different associated first signals 2044, for example, respective first signals with different oscillation frequencies, so as to provide distinguishable bent metal 2072 and proximity 2074 signal components in the signal from the magnetic sensing element 2050, wherein the respective signals would be demodulated by respective synchronous demodulators 2070. For example, in one embodiment, a 10 KHz first signal 2044.1 is applied to a first coil 42.1 on the top hinge 2018.1, and a 20 KHz first signal 2044.2 is applied to a first coil 42.2 on the bottom hinge 2018.2, and both frequencies are sensed substantially simultaneously by different associated magnetic sensing elements 2050 associated with the B-pillar and C-pillar of the vehicle 12, respectively.

The operating point of the magnetic sensor 2010, for example the level of magnetic flux 186 within the magnetic circuit 188 and the nominal current supplied to the at least one first coil 2042, under quiescent conditions, can be adjusted by adjusting the wire gage or number of turns of at least one first coil 2042.

The system safing or proximity detection can be enhanced by various means, including but not limited to placing a winding around the undercarriage, door opening, or hood of the automobile; placing a winding around the front fender of the automobile; placing a ferrite rod inside the hinge coil, or inside the striker coil for magnetic focusing; placing a ferrite rod coil in the gap or space between the doors; or placing a supplemental first coil 2042 in the side-view mirror molding, which extends sidewards away from the vehicle. An additional system safing supplemental first coil 2042, with proper phasing and with the magnetic circuit return properly adjusted, would substantially increase the system safing signal performance. For example, this coil could be about 3 inches in diameter and in a plane parallel to the door surface, or wound on a ferrite rod aligned to enhance the launch range and enhance the directivity for system safing. Moreover, by the combination of proximity detection and bent metal detection, together with a self-test of the associated at least one first coil 2042 and the magnetic sensing element 2050, the magnetic sensor 2010 is able to provide both safing and crash detection functions, thereby precluding the need for a separate crash accelerometer. The coils 2042, 2054 and 2062 of the magnetic sensor 2010 could, for example, be constructed of wire wound on an associated bobbin, and then placed over an existing component of the vehicle, for example a hinge 2018 or striker 170.

The coils or sensing elements may incorporate a ferrite or other high permeability magnetic core. Also, highly-tuned coils can be used for magnetic signal generation. Moreover, the width and length of coil bobbins can be adapted to steer the magnetic flux 186. Lastly, the at least one first coil 2042 or the at least one magnetic sensing element 2050 might incorporate ferrite rod coils placed under the vehicle chassis, in the vehicle headliner, in the “A” pillar, or in the “B” pillar, pointing towards the road.

Moreover, the signals associated with the magnetic sensor 2010 can be generated, adapted or processed in a variety of ways, including but not limited to:

-   -   1. Setting up an alternate frequency to create system safing on         the rear door 78 to enhance the system safing of the front door         78;     -   2. AM, FM or pulsed demodulation of the magnetic signature;     -   3. Multi-tone, multi-phase electronics;     -   4. A magnetically-biased, phase-shift oscillator for low-cost         pure sine wave generation;     -   5. A coherent synthetic or phased-locked carrier hardware- or         microprocessor-based system;     -   6. A system of microprocessor gain-or offset-tuning through D/A         then A/D self-adjust or self-test algorithm;     -   7. Placing a “standard” in the system safing field for magnetic         calibration;     -   8. Inaudible frequencies;     -   9. Microprocessor-generated crystal stabilized frequencies for         stability, including microprocessor D/A converter for coherent         sine-wave generation;     -   10. Wide-band system electronics;     -   11. Closed loop gain- and phase-control of the signal to a         sending-coil (i.e. AGC with the door 78 acting as a delay line),         wherein the gain- and phase-control signals are used as sensor         outputs;     -   12. AC or DC operation, wherein the DC portion of the signal         provides information from the net static magnetic flux 186 of         the door 78 in product with the velocity of the impact, but does         not provide proximity information, and the AC approach provides         the proximity field and allows the system to be ratiometric with         the known and stationary transmitter gain;     -   13. In accordance with experiments that have shown that the         phase varies as the magnetic gain across the door 78 varies, a         phase processor (FM) that has a lower signal-to-noise ratio than         a gain processor (AM);     -   14. Monitoring the power delivered by the coil driver,         particularly the bypass power, in order to detect impacts near         or at the hinge(s) magnetically energized with the at least one         first coil;     -   15. A series-resonant coil driver-circuit to increase current to         flow to the at least one first coil 2042 so as to improve the         signal-to-noise ratio, wherein the associated current to the at         least one first coil 2042 is monitored to provide a continuous         self-test of the at least one first coil 2042, as well as a         measure of the power drawn by the at least one first coil 2042;         and     -   16. Using another type of magnetic sensing element 2050, for         example a Hall effect or a Giant Magneto-resistive (GMR) device,         instead of a second coil 2054.

If both front doors are to be protected, then the effects of temperature and component variation may be mitigated by making a ratiometric measurement of comparable signals from one door 78 relative to another, wherein it is assumed that both doors will not be simultaneously impacted. The ratiometric measurement may also be used to augment the individual measurements from each door 78. Furthermore, a common oscillator may be used to generate a common signal used by each associated first coil 2042, so as to reduce cost and to synchronize the magnetic flux 186 generated at various locations in the vehicle 12.

Whereas the magnetic sensor 2010 has been illustrated herein with the door 78 as a principal sensing element, the magnetic sensor 2010 may generally be adapted to sensing the integrity of any component of any component capable of conducting magnetic flux 186, and would be advantageous for sensing large or long ferromagnetic parts. For example, the magnetic sensor 2010 can be adapted to sensing other body parts, such as fenders, that are attached to the main body of the vehicle by operatively connecting an at least one first coil 2042 between the body part and the main body at the point of attachment.

The proximity or leakage magnetic field comprising the above described second 2088 and third 2094 portions of the magnetic flux 186 can be useful for detecting magnetically permeable objects proximate to a vehicle 12, for example proximate to a door 78 of a vehicle 12; and for detecting the velocity of an object from the affect over time of the object on the permeance of the region proximate to the vehicle 12. This provides for what is termed herein a “radar mode” of operation useful for anticipatory collision sensing, with the following features:

-   -   1. The “radar mode” can be further augmented by the use of         independent carrier frequencies. With frequency differentiation         on the magnetic “transmitters” the system can determine and         differentiate the incoming “magnetically visible” object's         “height off of the earth” relative to the upper and lower hinge         position. A SUV will send “more signal” to the upper hinge as         compared with a low profile sports car.     -   2. The incoming object height information will also support pole         versus 214 style-hit scenarios.     -   3. The “radar mode” provides for anticipatory crash sensing,         adjacent lane awareness, blind spot awareness, a means for         measuring a following distance to a preceding vehicle, a sensor         for a collision avoidance system that, for example, could turn         the steering wheel as the result of an object detected in the         “magnetic fringing field of view” of the automobile door         described above, and a sensor for use in a system to         automatically center the vehicle between other vehicles in         adjacent driving lanes.     -   4. Some quantity of the magnetic flux generated by the hinge         coil will enter the space surrounding the automobile door and         return from that space and enter the striker coil.     -   5. Permeable objects will be detectable as magnetic “leakage”         flux lines from the door enter and exit the near-by-permeable         object.     -   6. The list of permeable objects “visible” to the door magnetic         fringe field includes, but is not limited to people or         relatively large animals, metal objects, automobiles, any object         of comparable size to the door and with a distinct permeance,         living trees comprising a permeable material.     -   7. The incoming velocity of these objects can be measured.     -   8. A state machine can be used to track object motion history         and “anticipate” a collision with an object having sufficient         velocity to be a danger to the occupant if the velocity does not         change. This pre-crash information is sometimes referred to as         information at a “negative time”.

Referring to FIG. 108, a magnetic sensor 2100 comprises a first coil 2042 (L₁) operatively associated with a magnetic circuit 188 of a vehicle body 168—schematically illustrated, for example, comprising a first magnetic path 2030 along a door 78 of the vehicle 12 and a second magnetic path 2032—distinct from the first magnetic path 2030—comprising the body 168, structure 2034, or powertrain 2036 of the vehicle 12, wherein the first 2030 and second 2032 magnetic paths together constitute a closed magnetic path 2040. The first coil 2042 (L₁) is operatively coupled to an electrical circuit 2102 adapted so that the first coil 2042 (L₁) in cooperation with the electrical circuit 2102 exhibits a resonant or near-resonant condition in association an oscillatory first signal 2044 applied by the electrical circuit 2102 to the first coil 2042 (L₁), which generates an associated time-varying magnetic flux 186, φ, in the magnetic circuit 188. In the example illustrated in FIG. 108, the electrical circuit 2102 comprises an oscillator 2104 adapted to drive a first resonant circuit 2106 comprising the first coil 2042 (L₁), a first capacitor 2108 (C_(S)) and a resistor 2110 (R_(S)) in series with the first coil 2042 (L₁), wherein the first signal 2044 from the oscillator 2104 is operatively coupled to the first coil 2042 through a first buffer amplifier 2112.

For example, the oscillator 2104 may generate either a sinusoidal or square wave signal, which can be either mono-polar or bi-polar, although a mono-polar signal is beneficial in simplifying the associated circuitry of the electrical circuit 2102 and it associated power supply. In one embodiment, the oscillator 2104 is adapted to oscillate at 20 KHz and the associated first resonant circuit 2106 is adapted to have an associated resonant frequency of 10 to 20 KHz. The associated electrical circuit 2102 is adapted to operate at about half the nominal voltage of the associated power supply of the associated electrical circuit 2102, so as to provide for continuous operation over the expected operating cycle of the power supply, e.g. vehicle battery. Accordingly, for a nominal 12 volt power supply, this oscillator 2104 generates a mono-polar signal of 0-6 volts. Generally, the nominal oscillation frequency of the oscillator 2104 may range between DC (no oscillation) and 100 KHz for a typical vehicle 12, but which may be 1 MHz or higher in a vehicle that has been augmented with supplemental magnetic materials such as mu-metal, ferrite or amorphous metal materials (e.g. METGLAS®). For example, in one set of embodiments, the oscillation frequency of the oscillator 2104 is adapted for the audio to near ultrasonic range of between 5 KHz and 30 KHz. The choice of a particular frequency can be affected by electromagnetic compatibility (EMC) issues associated with the magnetic sensor 2100 in the vehicle 12, for example, so as to avoid interference with other electronic systems in the vehicle, e.g. the AM radio receiver. In one approach, the frequency spectra of the one or more signals responsive to the magnetic flux 186, φ are measured responsive to a crash and analyzed so as to determine an upper bound on the frequencies of relevance to the crash for subsequent processing. Then, the associated oscillation frequency of the oscillator 2104 is adapted to be some factor greater than that upper bound frequency of the measured data, e.g. in accordance with the Nyquist criteria. For example, in one embodiment, the oscillation frequency may be adapted to be a factor of at least two times greater than the maximum frequency of interest, for example, a factor of 2.5. The associated nominal resonant frequency of the first resonant circuit 2106 is adapted to be either the same as or different from the oscillation frequency of the oscillator 2104, depending upon the particular embodiment. The voltage level of the oscillator 2104 and the resistance of the first resonant circuit 2106 are adjusted to provide the level of current through the first coil 2042 (L₁) necessary to provide a desired level of magnetic flux 186, φ in the associated magnetic circuit 188. For a given level of current through the first coil 2042 (L₁), an increase in the number of turns thereof increases the density of magnetic flux 186, φ thereby increasing the signal-to-noise ratio of the associated response signals.

Referring to FIG. 109, the first coil 2042 (L₁) can be modeled as an ideal inductor L₁′ in series with an ideal resistor R_(L1) representing the electrical resistance in the wire of the first coil 2042 (L₁), the series combination of which is in parallel with an ideal capacitor C_(L1) representing the inter-turn capacitance of the first coil 2042 (L₁). The oscillation frequency f₀ of the oscillator 2104 and the capacitance of the first capacitor 2108 (C_(S)) are adapted so that the series combination of the first coil 2042 (L₁) and the first capacitor 2108 (C_(S)) exhibits a resonant or near-resonant condition for at least one condition of the vehicle body 168. The inductance L₁′ of the first coil 2042 (L₁) is responsive to the associated coil geometry and to the reluctance of the associated magnetic circuit 188, both of which can be responsive to a crash. For example, a crash involving the location of the first coil 2042 (L₁) could distort the coil and possibly cause one or more turns of the coil to become shorted, which would affect the effective inductance L₁′, resistance R_(L1) and capacitance C_(L1) of the first coil 2042 (L₁). Furthermore, a crash affecting elements of the magnetic circuit 188 can affect the reluctance thereof, which affects the inductance of the first coil 2042 (L₁) magnetically coupled thereto in accordance with the relationship L₁′=N²/

, wherein L₁′ is the self-inductance of the first coil 2042 (L₁), N is the number of turns of the first coil 2042 (L₁), and

is the magnetic reluctance of the flux path, i.e. the magnetic circuit 188, to which the first coil 2042 (L₁) is magnetically coupled.

A frequency domain representation of the current through a series combination of an inductor L, capacitor C and resistor R, responsive to a source voltage V(jω) having an oscillatory radian frequency ω is given by:

$\begin{matrix} {{I\left( {j\;\omega} \right)} = \frac{{- j} \cdot \omega \cdot {V\left( {j\;\omega} \right)}}{L \cdot \left( {\omega^{2} - {{\frac{R}{L} \cdot j}\;\omega} - \frac{1}{LC}} \right)}} & (1) \end{matrix}$ and the voltage V_(L) across the inductor L is given by:

$\begin{matrix} {{V_{L}\left( {j\;\omega} \right)} = {\frac{\omega^{2} \cdot {V\left( {j\;\omega} \right)}}{\omega^{2} - {{\frac{R}{L} \cdot j}\;\omega} - \frac{1}{LC}} = \frac{V\left( {j\;\omega} \right)}{1 - {j \cdot 2 \cdot \zeta \cdot \frac{\omega_{n}}{\omega}} - \left( \frac{\omega_{n}}{\omega} \right)^{2}}}} & (2) \end{matrix}$ wherein the resonant frequency ω_(n) and damping ratio ζ are defined respectively as

$\begin{matrix} {\omega_{n} = {\frac{1}{\sqrt{LC}} = {{\frac{1}{2\;\pi\; f_{n}}\mspace{14mu}{and}\mspace{14mu}\zeta} = \frac{\sqrt{\left( \frac{R}{L} \right) \cdot \left( {R \cdot C} \right)}}{2}}}} & (3) \end{matrix}$ and ω_(n) and f_(n) are the radian and natural resonant frequencies respectively. For a component of the oscillatory first signal 2044 at the resonant frequency, i.e. at resonance, the inductive and capacitive reactances of the inductor L and capacitor C respectively, i.e. jωL and

$\frac{1}{j\;\omega\; C}$ respectively, cancel one another, resulting in an impedance Z=R of the series combination. At resonance, current I through the inductor L has a value of I=V/R, and the voltage V_(L) across the inductor L is given by:

$\begin{matrix} {{V_{L}\left( {j\;\omega_{n}} \right)} = {\frac{V\left( {j\omega}_{n} \right)}{{- j} \cdot 2 \cdot \zeta} = {j \cdot \frac{V\left( {j\;\omega_{n}} \right)}{2 \cdot \zeta}}}} & (4) \end{matrix}$

Accordingly, referring to FIG. 110, for the first resonant circuit 2106 illustrated in FIG. 108, the magnitude of the current I_(L1) through the first coil 2042 (L₁), and the corresponding magnitude of the magnetic flux 186, φ, induced thereby in the magnetic circuit 188 is maximized when the first signal 2044 from the oscillator 2104 is at the resonant frequency f_(n)=2πω_(n) of the first resonant circuit 2106. For a given level of the first signal 2044, this series resonant condition maximizes the magnitude of the magnetic flux 186, φ, which provides for maximizing both the magnitude and signal-to-noise ratio of a crash related response thereto. In addition to providing for an improved signal-to-noise ratio of the response signal, the series resonant condition provides for accommodating lower levels of the first signal 2044 than would otherwise be possible. For example, the level of the first signal 2044 could be one volt, or less, if necessary.

Stated in another way, for a given magnetic flux 186, φ, to be generated in the magnetic circuit 188 by the first coil 2042 (L₁) responsive to a first signal 2044, the necessary magnitude of the first signal 2044 is lower for a series resonant condition than for a non-resonant condition. This is beneficial in an automotive environment—wherein the battery voltage is subject to substantial variation during its life cycle, depending upon the state of charge, the load levels, and the operativeness of the associated charging system—by providing for operation using a single-ended nominal 12 volt battery power supply to the electrical circuit 2102 without requiring either an associated voltage magnification circuit or a bi-polar power supply circuit. For example, the series resonant condition provides for operating at a voltage substantially less than the nominal battery voltage—e.g. operating at about 6 volts for a 12 volt nominal battery voltage—so as to provide for uninterrupted sensing during conditions of low battery voltage. This reduces the complexity and cost of the power supply for the associated electrical circuit 2102, and reduces associated power consumption by the components thereof. Operation at or near resonance is also beneficial in improving the electromagnetic compatibility (LMC) of the magnetic sensor 2100 with other systems.

In one embodiment, the resistance R_(S) of the resistor 2110 (R_(S)) is lower than the resistance R_(L1) of the first coil 2042 (L₁) so as to reduce power consumption by the resistor 2110 (R_(S)) and so as to increase the sensitivity of the current in the first resonant circuit 2106 to changes in the resistance R_(L1) of the first coil 2042 (L₁). At resonance, the inductive reactance of the first coil 2042 (L₁) cancels the capacitive reactance of the first capacitor 2108 (C_(S)), so that the component of current in the first resonant circuit 2106 at the resonant frequency is given by the ratio of the source voltage—i.e. the voltage of the first signal 2044 from the oscillator 2104—divided by the total resistance of the first resonant circuit 2106—i.e. the sum of the resistance R_(L1) of the first coil 2042 (L₁), the resistance R_(S) of the series resistor 2110 (R_(S)), and the resistance of other associated conductors in the first resonant circuit 2106, e.g. coil leads, cables, printed circuitry, and connector(s). The level of the maximum current level at resonance in the first resonant circuit 2106 can be set to a desired level by adjusting either the total series resistance thereof or the magnitude of the first signal 2044, or by adjusting both. The magnitude of the associated magnetic flux 186, φ generated by the first coil 2042 (L₁) is proportional to the product of the number of turns N of the first coil 2042 (L₁) times the current I therein, wherein the current I is given by the ratio of the level V of the first signal 2044 divided by the total resistance of the first resonant circuit 2106, or

$\begin{matrix} {{\phi \sim {N \cdot I}} = \frac{N \cdot V}{R_{Total}}} & (5) \end{matrix}$

For example, the maximum current I or associated maximum magnetic flux 186, φ may be adjusted to satisfy EMC requirements—e.g. on radiated power—by adjusting either the number of turns N or the total resistance R_(Total) without impacting the associated operating voltage V of the system, which, for example, may be a mono-polar +6 volts for a nominal 12 volt battery powered system.

The self-capacitance C_(L1) of the first coil 2042 (L₁)—which increases with increasing number of turns N of the first coil 2042 (L₁),—in combination with the self-inductance L₁′ of the first coil 2042 (L₁), provides for inherent low-pass filtering of signals applied to or affecting the first coil 2042 (L₁). For example, the first signal 2044 from a square wave oscillator 2104, e.g. a TTL (Transistor Transistor Logic) oscillator, would exhibit harmonics of higher frequency than the fundamental oscillation frequency f₀. These harmonics can be attenuated by this effective low-pass filter so as to reduce, or effectively preclude, the generation of components of magnetic flux 186, φ at the harmonic frequencies—which if otherwise generated might cause undesirable electromagnetic signals—thereby improving the electromagnetic compatibility (EMC) of the associated magnetic sensor 2100. Furthermore, increased self-capacitance reduces the electromagnetic susceptibility of the magnetic sensor 2100 to external interference.

In accordance with a first embodiment of the magnetic sensor 2100.1—in what is referred to as a transformer mode of operation—the magnetic flux 186, φ generated in the magnetic circuit 188 by the first coil 2042 located at a first location 2048 on the magnetic circuit 188, responsive to the first signal 2044 applied thereto, is sensed by a magnetic sensing element 2050, e.g. a second coil 2054 (L₂), at a second location 2052 on the magnetic circuit 188, which generates a second signal 2114 responsive to the reluctance of the magnetic circuit 188, for example, responsive to a crash affecting at least one element of the magnetic circuit 188, or responsive to a magnetic-flux-influencing object proximate to a proximity flux component 2088 of the magnetic flux 186 of the magnetic circuit 188. The magnetic sensor 2100.1 can be adapted so as to provide for sensing either the magnitude of the second signal 2114 or components thereof, e.g. DC or AC, or for sensing the phase of the second signal 2114 in relation to that of the associated first signal 2044. For example, in one embodiment that operates at a relatively low frequency, the relative phase between the first 2044 and second 2114 signals might be used as a the primary measure to detect a crash.

Referring to FIG. 108, in accordance with a second embodiment of the magnetic sensor 2100.2, the voltage level and the signal-to-noise ratio of the second signal 2114 can be enhanced by incorporating a second resonant circuit 2116 comprising a second capacitor 2118 (C_(P)) in parallel with the second coil 2054 (L₂), adapted to exhibit a resonant or near-resonant condition in combination therewith responsive to an oscillatory magnetic flux 186 generated responsive to the oscillatory first signal 2044. The signal from the second resonant circuit 2116 is biased with a DC offset V_(REF) equal to about half the value of the voltage V_(DD) of the associated power supply of the associated electrical circuit 2102′, so as to provide for a mono-polar second signal 2114 from the second resonant circuit 2116, thereby simplifying the associated circuitry and power supply requirements. The voltage across the parallel combination of the second coil 2054 (L₂) and the second capacitor 2118 (C_(P)) is input to a second buffer amplifier 2120, the output of which is AC coupled through a first amplifier 2122 and a first coupling capacitor 2124 to a first demodulator 2126, e.g. a synchronous demodulator, which detects the modulated amplitude of the carrier signal underlying the second signal 2114. The output from the first demodulator 2126 is directly coupled to a second amplifier 2128, the output of which is coupled through a first analog-to-digital converter 2130—e.g. as a bent metal signal component 2072 of the second signal 2114—to a processor 2132 for processing as described hereinabove. The output from the first demodulator 2126 is AC coupled through a second coupling capacitor 2134 to a third amplifier 2136, the output of which is coupled through a second analog-to-digital converter 2138—e.g. as a proximity signal component 2074 of the second signal 2114—to the processor 2132 for processing as described hereinabove.

Referring to FIG. 111, the second coil 2054 (L₂) can be modeled as an ideal inductor L₂′ in series with an ideal resistor R_(L2) representing the electrical resistance of the wire of the second coil 2054 (L₂), the series combination of which is in parallel with an ideal capacitor C_(L2) representing the inter-turn capacitance of the second coil 2054 (L₂). The oscillatory magnetic flux 186, φ linked with the second coil 2054 (L₂) induces a voltage therein in accordance with Faraday's law of induction, and this induced voltage is represented in FIG. 111 by an oscillatory voltage source E₂ in series with the associated ideal inductor L₂′. Although the second capacitor 2118 (C_(P)) is connected in parallel with the second coil 2054 (L₂), for purposes of modeling the associated second signal 2114, the second capacitor 2118 (C_(P)) and the second coil 2054 (L₂) can also be considered to be connected in series since these are the only two elements connected to one another. More particularly, as illustrated in FIG. 111, the combination of the second coil 2054 (L₂) and the second capacitor 2118 (C_(P)) can be modeled as an ideal inductor L₂′ in series with an ideal resistor R_(L2), an oscillatory voltage source E₂, and with a total capacitance C_(P) _(—) _(Total) given by the sum of the capacitances of the ideal capacitor C_(L2) and the second capacitor 2118 (C_(P)), i.e. C_(P) _(—) _(Total)=C_(L2)+C_(P). The associated second resonant frequency f_(n) _(—) ₂ of the second resonant circuit 2116 is given by:

$\begin{matrix} {\omega_{{n\_}2} = {\frac{1}{\sqrt{L_{2}^{\prime}C_{P\_ Total}}} = \frac{1}{2\;\pi\; f_{{n\_}2}}}} & (6) \end{matrix}$

The capacitance of the second capacitor 2118 (C_(P)) and the inductance L₂′ of the second coil 2054 (L₂) are adapted, for example, to set the second resonant frequency f_(n) _(—) ₂ to correspond to the oscillation frequency f₀ of the oscillator 2104. The inductance L₂′ of the second coil 2054 (L₂) is responsive to the associated coil geometry and to the reluctance

of the associated magnetic circuit 188, either of which can be responsive to a crash. For example, a crash involving the location of the second coil 2054 (L₂) could distort the second coil 2054 (L₂) and possible cause one or more turns thereof to become shorted, which would affect the effective inductance L₂′, resistance R_(L2) and capacitance C_(L2) thereof. Furthermore, a crash affecting elements of the magnetic circuit 188 can affect the reluctance

thereof, which affects the inductance of the second coil 2054 (L₂) operatively associated therewith, in accordance with the relationship L₂′=N₂ ²/

, wherein L₂′ is the self-inductance of the second coil 2054 (L₂), N₂ is the number of turns of the second coil 2054 (L₂), and

is the magnetic reluctance

of the flux path, i.e. magnetic circuit 188, to which the second coil 2054 (L₂) is coupled. Furthermore, the sensitivity of a change in inductance L₂′ to a change in reluctance

increases with an increasing number of turns N₂. At resonance, i.e. wherein the magnetic flux 186, (oscillates at the second resonant frequency f_(n) _(—) ₂, the current through the second coil 2054 (L₂) and the second capacitor 2118 (C_(P)) is maximized to a level that is responsive to the associated series resistance of the second resonant circuit 2116; and the second signal 2114 (V_(OUT))—given by the voltage across the second capacitor 2118 (C_(P))—is also thereby maximized, as illustrated in FIG. 112. The impedance of the parallel elements of the second resonant circuit 2116 is relatively high at resonance, and this high impedance is buffered by the second buffer amplifier 2120 (i.e. a voltage follower) shown in FIG. 108, so as to reduce loading thereof by the AC coupled first demodulator 2126.

The parallel combination of the second coil 2054 (L₂) and the second capacitor 2118 (C_(P)) is beneficial for improving electromagnetic compatibility (EMC) by reducing susceptibility to externally generated electromagnetic fields, wherein at the associated relatively high frequencies, the impedance of the second capacitor 2118 (C_(P)) is relatively low, thereby limiting the associated signal levels that can be generated thereacross. Accordingly, the second resonant circuit 2116 provides for enhancing or maximizing the level of the second signal 2114 for signals of interest, and for attenuating undesirable signals associated with electromagnetic noise.

It should be understood that the first and second embodiments of the magnetic sensor 2100 can be practiced either jointly in combination with one another, as illustrated in FIG. 108, or individually—one or the other. In one mode of operation, the first and second embodiments of the magnetic sensor 2100 provide distributed crash sensing, wherein the inductance of the first 2042 (L1) and second 2054 (L2) coils, and the mutual inductance therebetween, is responsive to a crash-induced deflection or deformation of the elements of the associated magnetic circuit 188, or responsive to magnetic-field-influencing objects proximate thereto, which thereby affects the magnetic flux 186, φ therein generated responsive to the first signal 2044 applied to the first coil 2042 (L₁) at the first location 2048, and which affects the second signal 2114 generated by the magnetic sensing element 2050, e.g. second coil 2054 (L₂), responsive to the magnetic flux 186, φ thereat. In another mode of operation, referred to as a safing mode, the first and second embodiments of the magnetic sensor 2100 provide for a nominal level of the second signal 2114 for a nominal state of the magnetic circuit 188, and changes of the second signal 2114 therefrom provide an indication of changes of or to the elements of the magnetic circuit 188, e.g. the first coil 2042 (L₁), the first 2030 or second 2032 magnetic paths, or the magnetic sensing element 2050/second coil 2054 (L₂). Accordingly, the second signal 2114 can be compared with a threshold to determine whether the associated magnetic sensor 2100.1, 2100.2 is in an acceptable nominal state prior to the subsequent detection of a crash.

In accordance with a third embodiment of the magnetic sensor 2100.3, the electrical circuit 2102 associated with the first coil 2042 (L₁) is adapted to sense one or more variables associated with the first resonant circuit 2106, for example, the voltage across the first coil 2042 (L₁), the current through the first coil 2042 (L₁) as measured by the voltage across the resistor 2110 (R_(S)) in series with the first coil 2042 (L₁), or the voltage across the first capacitor 2108 (C_(S)); so as to provide for determining therefrom a measure responsive to the inductance or resistance of the first coil 2042 (L₁), for example, the inductance L₁′ of the first coil 2042 (L₁), the magnitude of the voltage across the first coil 2042 (L₁), the magnitude of the current through the first coil 2042 (L₁), the phase angle between the voltage across the first coil 2042 (L₁) and the current through the first coil 2042 (L₁), the reactive power applied to the first coil 2042 (L₁), or the real power that is absorbed by the first coil 2042 (L₁). The measure responsive to the inductance or resistance of the first coil 2042 (L₁) may then be used to either diagnose the operativeness of the first resonant circuit 2106—particularly the first coil 2042 (L₁)—or to detect the occurrence of a crash in accordance with a self-inductance mode of operation—particularly impacts proximate to the first location 2048, (e.g. the hinge 2018 side of the door 78) of the first coil 2042 (L₁),—for example, in accordance with the teachings of U.S. application Ser. No. 09/648,606 filed on Aug. 26, 2000, now U.S. Pat. No. 6,587,048, which is incorporated herein by reference. For example, the current in the first coil 2042 (L₁) can be sensed and compared with one or more thresholds to determine if the first resonant circuit 2106 is operating normally for a nominal condition of the vehicle 12, or, for example, if one or more turns of the first coil 2042 (L₁) are shorted. An impact to the vehicle 12 affecting the magnetic circuit 188 would modulate the voltage across, the current through, or the inductance of the first coil 2042 (L₁) to which the above-identified measures are responsive. The measure responsive to the inductance or resistance of the first coil 2042 (L₁) can be detected and sensed in real time so as to provide for real time detection of the operativeness of the first resonant circuit 2106, e.g. so as to determine whether or not the first coil 2042 (L₁) is generating a magnetic flux 186, φ in the magnetic circuit 188. Furthermore, different magnetic sensors 2100 at different locations in the vehicle 12, e.g. the A-pillar, B-pillar or C-pillar of the vehicle 12 may be adapted to verify the operativeness of one another, and thereby provide for mutual safing of different magnetic sensors 2100.

The current I in the first coil 2042 (L₁) generates a magnetic flux 186, φ in the associated magnetic circuit 188. This magnetic flux 186, φ stores an associated energy therein which is in balance with both the energy transferred thereto by the first coil 2042 (L₁), and with associated energy losses, e.g. resulting from either eddy currents, hysteresis or radiation. A mechanical perturbation of one or more elements of the magnetic circuit 188, e.g. the door 78, affects this energy balance, resulting in a corresponding affect on the current I received or absorbed by the first coil 2042 (L₁), and it is believed that the magnitude of this affect is related to the mechanical energy associated with the associated mechanical perturbation.

Stated in another way, the inductance L₁′ of the first coil 2042 (L₁) is responsive to the associated coil geometry (including wire size, number of turns, and turn shape and radii) and to the reluctance of the associated magnetic circuit 188. Accordingly, a change to either the magnetic circuit 188, or the to coil geometry,—e.g. responsive to a crash—will cause an associated change in the associated inductance L₁′ of the first coil 2042 (L₁), which in turn causes an associated change in the impedance Z_(L) thereof responsive to an oscillatory signal from the oscillator 2104, which in turn causes an associated change in the impedance Z of the first resonant circuit 2106 to which the first signal 2044 from the oscillator 2104 is applied. Accordingly, for a first signal 2044 having a constant amplitude V, the resulting current I through the first coil 2042 (L₁) given as I=V/Z will vary responsive to the value of Z, with is responsive to and indicative of the mechanical perturbation of either the associated magnetic circuit 188 or the first coil 2042 (L₁).

Furthermore, certain types of crashes, e.g. pole impacts, the extent to which a crash induced perturbation of the magnetic circuit 188 influences the resulting current I in the first coil 2042 (L₁) is responsive to the proximity of the crash location to the first coil 2042 (L₁). Accordingly, in accordance with one embodiment, the magnitude of the variation in current I in the first coil 2042 (L₁) can be used as a measure of the proximity of the crash to the first coil 2042 (L₁). In accordance with another embodiment, the variation in current I in the first coil 2042 (L₁) in relation to the variation in the associated signal from one or more associated magnetic sensing elements 2050 can be used to determine the location of the crash in relation to the locations of the first coil 2042 (L₁) and the one or more associated magnetic sensing elements 2050. Generally, the modulation of the current I in the first coil 2042 (L₁) is useful for sensing crash severity and location, and for verifying the operativeness of the first coil 2042 (L₁). By relatively increasing or maximizing the current I in the first coil 2042 (L₁) using a first resonant circuit 2106 as described hereinabove, the associated detection sensitivity is relatively increased or maximized.

Referring to FIG. 108, in accordance with a first embodiment of a subsystem for sensing one or more variables associated with the first resonant circuit 2106, both the voltage across the first coil 2042 (L₁), and the voltage across the resistor 2110 (R_(S)), are sensed, the latter of which provides a measure of the current I through the first coil 2042 (L₁). The voltage across the first coil 2042 (L₁) is input to a differential amplifier 2140 operatively coupled to third analog-to-digital converter 2142, either directly or through a second demodulator 2144, and the output of the third analog-to-digital converter 2142 is input to the processor 2132. The voltage V_(RS) across the resistor 2110 (R_(S)) is input to a fourth amplifier 2146 operatively coupled to fourth analog-to-digital converter 2148, either directly or through a third demodulator 2150, and the output of the fourth analog-to-digital converter 2148 is input to the processor 2132. Notwithstanding that the fourth amplifier 2146 is illustrated as a single-ended amplifier, it should be understood that the fourth amplifier 2146 may also be adapted as a differential amplifier, with the differential inputs thereof adapted to measure the voltage signal across the resistor 2110 (R_(S)).

It should be understood, that the analog-to-digital converters 2130, 2138, 2142 and 2148 would cooperate with associated low pass anti-aliasing filters either incorporated therein, or incorporated in other signal conditioning elements that preprocess the signal(s) thereto, so as to prevent high frequency information from aliasing as corresponding lower frequency information in the sampled signals. For example, in accordance with the Nyquist sampling criteria, the sampling frequency of the analog-to-digital converters 2130, 2138, 2142 and 2148 would be at least twice as great as the cut-off frequency of the associated anti-aliasing filter. It is beneficial to adapt the anti-aliasing filter, for example, by using a single pole anti-aliasing filter, so as to provide for avoiding excessive phase shift or delay in the filtered signal, so as to provide for an associated relatively fast step response.

The second 2144 and third 2150 demodulators, if present, provide for detecting one or more of a magnitude, a phase, a relative phase, in in-phase component or a quadrature-phase component of the respective input signals to the respective demodulators 2144, 2150. More particularly, each respective input signal comprises a carrier at the oscillation frequency f₀, which carrier is modulated by a respective modulation signal, and the demodulators 2144, 2150, if present, provide for generating one or measures of amplitude or phase—including in-phase and quadrature-phase signal components—responsive to associated characteristics of the respective modulation signal. Depending upon their configuration, the second 2144 and third 2150 demodulators, if present, may be connected either directly to the processor 2132, e.g. to one or more digital inputs, or through associated third 2142 and fourth 2148 analog-to-digital converters. Furthermore, the functions of the second 2144 and third 2150 demodulators could be combined in a single demodulator that generates either analog or digital output signals, or both, and is which appropriately connected to the processor 2132. Yet further, one or more demodulation functions could also be carried out directly by the processor 2132 on one or more of the respective input signals. Yet further, one or all of the demodulators 2126, 2144 or 2150 (e.g. the second demodulator 2144 as illustrated in FIG. 108) may be operatively coupled to the oscillator 2104 so as to facilitate phase processing of the associated signal(s). For example, the relative phase of the current through and voltage across the first coil 2042 (L₁) can be affected by either the opening of the door 78, or an impact thereto resulting from a crash.

The voltage V_(RS) across the resistor 2110 (R_(S)) provides a measure of the current I therethrough, given by I=V_(RS)/R_(S), which is also a measure of the current through the first coil 2042 (L₁) in series therewith. The measure of current I will be responsive to the total resistance R_(Total) of the first resonant circuit 2106 and to the sum of the inductive and capacitive reactances of the first coil 2042 (L₁) and the first capacitor 2108 (C_(S)) respectively, the latter of which sum to zero at resonance. Increasing the gain of the fourth amplifier 2146 increases the sensitivity of the measure of current I to the resistance R_(L1) of the first coil 2042 (L₁), and accordingly, the sensitivity to detecting whether one or more turns thereof are shorted. A shorting of one or more coils of the first coil 2042 (L₁) causes the associated current I to increase. Furthermore, if one or more turns of the first coil 2042 (L₁) are shorted, then the self-inductance L₁′ of the first coil 2042 (L₁) would also be affected, e.g. reduced, which would in turn affect the current I and the associated measure thereof, and the total reactance of the first resonant circuit 2106 would become increasingly capacitive reactive, thereby affecting the phase of the current I through the resistor 2110 (R_(S)) relative to the voltage of the first signal 2044 applied by the oscillator 2104. The self-inductance L₁′ of the first coil 2042 (L₁) is also responsive to the reluctance

of the associated magnetic circuit 188, changes to which—e.g. responsive to a crash or a proximate object—also affect the current I and the associated measure thereof. It is expected that the sensitivity of the self-inductance L₁′ of the first coil 2042 (L₁) to changes in the reluctance

of the associated magnetic circuit 188 can be increased by increasing the number of turns of the first coil 2042 (L₁). Additional fourth amplifiers 2146 and associated electronics may be added to provide for a plurality of current responsive signals, each having a different level of associated amplifier gain and resulting sensitivity. For example, a different sensitivity might be used for detecting changes of resistance R_(L1)—e.g. caused by shorted turn condition—of the first coil 2042 (L₁) than might be used for detecting crash-induced changes to the inductance L₁′ thereof. Alternatively, a single gain-controllable fourth amplifier 2146 could be used, with the gain thereof controlled by the processor 2132.

For a pure inductor L, the relationship between the voltage V_(L) across to the current I_(L) through the inductor L is given by:

$\begin{matrix} {{V_{L} = {L \cdot \frac{\mathbb{d}I_{L}}{\mathbb{d}t}}}{or},{{in}\mspace{14mu}{the}\mspace{14mu}{frequency}\mspace{14mu}{domain}},{{V_{L}\left( {j\;\omega} \right)} = {j\;{\omega \cdot L \cdot {I\left( {j\;\omega} \right)}}}}} & (7) \end{matrix}$

Accordingly, for an ideal inductor, the current I therethrough lags the voltage V_(L) thereacross by 90 degrees, and in the frequency domain, the inductance is given by:

$\begin{matrix} {L = \frac{V_{L}\left( {j\;\omega} \right)}{j\;{\omega \cdot {I\left( {j\;\omega} \right)}}}} & (8) \end{matrix}$

Alternatively, in the time domain:

$\begin{matrix} {L = \frac{\int_{t_{0}}^{t_{1}}{{V_{L}(t)} \cdot \ {\mathbb{d}t}}}{{I_{L}\left( t_{1} \right)} - {I_{L}\left( t_{0} \right)}}} & (9) \end{matrix}$

However, for a real inductor, e.g. first coil 2042 (L₁) represented by a the second-order system illustrated in FIG. 109, the phase angle between the current through the inductor L₁ and the voltage thereacross will be different from 90 degrees. Accordingly, the phase angle between the measure of current I—from the voltage across the resistor 2110 (R_(S))—and the voltage V_(L) across the first coil 2042 (L₁) can be used to augment the calculation of the inductance of the first coil 2042 (L₁), so as to account for the affects of the associated resistance R_(L1) and/or capacitance C_(L1). Other changes to the resistance of the first resonant circuit 2106, i.e. changes external to the first coil 2042 (L₁), e.g. changes to the resistance of an associated connector—e.g. as caused by a loose connector or faulty connection—would not affect the phase angle between the measure of current I and the voltage across the first coil 2042 (L₁), but would affect both the magnitude of the current I and the phase angle of this current I relative to the first signal 2044.

The processor 2132 senses the voltage V_(L) and current I signals in real time in order to either diagnose a failure of or change to either the first coil 2042 (L₁) or elements of the associated first resonant circuit 2106, or to discriminate a crash or other condition affecting the magnetic circuit 188. In addition to using the magnitudes of the voltage V_(L) and current I, the processor can also use the relative phase thereof, or the phase of either the voltage V_(L) of current I relative to that of the first signal 2044, in order to determine, for example, the inductance L₁′ or impedance of the first coil 2042 (L₁), the resistance R_(L1) thereof, or the resistance of the first resonant circuit 2106.

The processor 2132 may further determine the power applied to the first coil 2042 (L₁)—either reactive (V*I), real (V*I*cos (θ)), or both—which can be used as addition information for either failure detection, crash sensing, or sensing some other measure responsive to the reluctance

of the magnetic circuit 188.

The quality factor, or Q, of the first resonant circuit 2106 is related to the bandwidth of the magnetic sensor 2100, and is affected by the resistance of the first resonant circuit 2106—i.e. either the intrinsic resistance of the coil, the resistance of the associated series resistor 2110 (R_(S)), or the equivalent series resistance (ESR) of the associated first capacitor 2108 (C_(S)). Accordingly, the Q of the first resonant circuit 2106 can be set or adjusted by setting or adjusting the associated resistance of the first resonant circuit 2106, for example, either by adjusting the intrinsic resistance of the first coil 2042 (L₁)—which is described more fully hereinbelow,—or by adjusting the resistance of the series resistor 2110 (R_(S)). The overall sensitivity of the magnetic sensor 2100 to associated magnetic disturbances in or to the magnetic circuit 188 is affected by the relative amount by which the oscillation frequency differs from the resonant frequency of the first resonant circuit 2106, and this sensitivity to that change is affected by the Q of the first resonant circuit 2106. For example, this sensitivity or gain is highest when the oscillation frequency is equal to the resonant frequency, and is reduced as the relative difference increases, as illustrated in FIG. 110, wherein the sensitivity of this reduction to changes in the relative frequency difference is directly related to the Q of the first resonant circuit 2106—as Q increases, sensitivity becomes more sensitive to the relative frequency difference.

In accordance with a second embodiment of a subsystem for sensing one or more variables associated with the first resonant circuit 2106, the voltage V_(L) across the first coil 2042 (L₁) is sensed as described hereinabove, without separately sensing the voltage V_(RS) across the resistor 2110 (R_(S)). The voltage V_(L) across the first coil 2042 (L₁) will be responsive to the current I through the first coil 2042 (L₁) as follows: V _(L) =I·Z _(L)  (10) where Z_(L) is the impedance of the first coil 2042 (L₁). The current I through the first resonant circuit 2106 is given by:

$\begin{matrix} {I = \frac{V}{Z_{L} + Z_{CS} + R_{S}}} & (11) \end{matrix}$ where V is the voltage of the first signal 2044, Z_(CS) is the impedance of the first capacitor 2108 (C_(S)), and R_(S) is the impedance of the resistor 2110 (R_(S)) (if present). The impedance Z_(L) of the first coil 2042 (L₁) is then given as a function of the voltages V of the first signal 2044 and V_(L) across the first coil 2042 (L₁) as follows:

$\begin{matrix} {Z_{L} = \frac{Z_{CS} + R_{S}}{\frac{V}{V_{L}} - 1}} & (12) \end{matrix}$

For example, assuming that the voltage V of the first signal 2044, the impedance Z_(C) the first capacitor 2108 (C_(S)), and the impedance R_(S) of the resistor 2110 (R_(S)) (if present) are constant, then the impedance Z_(L) of the first coil 2042 (L₁) is given as a function of the voltage V_(L) thereacross.

In accordance with a third embodiment of a subsystem for sensing one or more variables associated with the first resonant circuit 2106, the voltage V_(RS) across the resistor 2110 (R_(S)) is sensed as described hereinabove, without separately sensing the voltage V_(L) across the first coil 2042 (L₁). The voltage V_(RS) across the resistor 2110 (R_(S)) is responsive to the current I_(L) through the first coil 2042 (L₁) as described hereinabove, and is responsive to the condition of resonance as illustrated in FIG. 110. Furthermore, the relationship between the voltage V_(RS) across the resistor 2110 (R_(S))—or the associated measure of current I therethrough—and the voltage V of the first signal 2044 is responsive to the impedances Z_(L) and Z_(CS) of the first coil 2042 (L₁) and first capacitor 2108 (C_(S)) respectively and the resistance R_(S) of the resistor 2110 (R_(S)), e.g. as illustrated by equation (11) hereinabove.

In accordance with a fourth embodiment of a subsystem for sensing one or more variables associated with the first resonant circuit 2106, the voltage V_(C) across the first capacitor 2108 (C_(S))—or the voltage (V_(C)+V_(RS)) across the series combination of the first capacitor 2108 (C_(S)) and resistor 2110 (R_(S))—can be sensed as an alternative to, or in addition to, sensing the voltage V_(L) across the first coil 2042 (L₁) or the voltage V_(RS) across the resistor 2110 (R_(S)). For example, the voltage V_(L) across the first coil 2042 (L₁) is given by: V _(L) =V ₁−(V _(CS) +V _(RS))  (13)

Referring to FIGS. 108 and 113, in accordance with a fifth embodiment of a subsystem for sensing one or more variables associated with the first resonant circuit 2106, the relative phase of third 2152 and fourth 2154 signals, e.g. the voltage V_(L) across the first coil 2042 (L₁) and the voltage V_(RS) across the resistor 2110 (R_(S)), is determined directly by the processor 2132 by an associated process 1300, wherein the third 2152 (V_(L)) and fourth 2154 (V_(RS)) signals are input to the processor 2132 through respective third 2142 and fourth 2148 analog-to-digital converters, are read by the processor in step (1302). In step (1304), if a phase timer has been previously started, then in step (1306) the phase timer is incremented, wherein the phase timer measures the time difference between associated positive-going zero crossings of the third 2152 (V_(L)) and fourth 2154 (V_(RS)) signals, and thereby is used to generate a measure of the relative phase thereof. In step (1310), a first average value V _(L) of the third signal 2152 (V_(L)) is determined, for example, using a running average or low pass filtering process. In step (1312), a second average value V _(RS) of the fourth signal 2154 (V_(RS)) is determined, for example, using a running average or low pass filtering process, e.g. similar to that used in step (1310). The respective average values V _(L) and V _(RS) represent the long term average values of the respective third 2152 (V_(L)) and fourth 2154 (V_(RS)) signals, which, for example, for an associated mono-polar electrical circuit 2102 would be corresponding non-zero bias values about which oscillate the associated oscillatory third 2152 (V_(L)) and fourth 2154 (V_(RS)) signals. For example, for a sinusoidal signal oscillating between extremes of +1 and +5 volts, the associated average value would be +3 volts, or its equivalent representation in the processor 2132. Then, in step (1314), the third signal 2152 (V_(L)) is compared with the associated first average value V _(L), and if the third signal 2152 (V_(L)) is greater, then, in step (1316), an associated first binary value V*_(L) is set to one; otherwise, in step (1318), the associated first binary value V*_(L) is set to zero. Then, in step (1320), if the first binary value V*_(L) has undergone a transition from zero to one—thereby exhibiting a leading edge, and indicating the occurrence of a positive-going zero crossing of the third signal 2152 (V_(L)),—then, in step (1322), the phase timer is reset to an initial value, e.g. zero, and then started. Following step (1322), or otherwise from step (1320), in step (1324), the fourth signal 2154 (V_(RS)) is compared with the associated second average value V _(RS), and if the fourth signal 2154 (V_(RS)) is greater, then, in step (1326), an associated second binary value V*_(RS) is set to one; otherwise, in step (1328), the associated second binary value V*_(RS) is set to zero. Then, in step (1330), if the second binary value V*_(RS) has undergone a transition from zero to one—thereby exhibiting a leading edge, and indicating the occurrence of a positive-going zero crossing of the fourth signal 2154 (V_(RS)),—then in step (1332) the value of the phase timer is stored, and the process repeats with step (1302). Otherwise, from step (1330), the process repeats with step (1302). A stored value of the phase timer less than a value corresponding to a period of a half wave length corresponds to the third signal 2152 (V_(L)) lagging with respect to the fourth signal 2154 (V_(RS)); a stored value of the phase timer greater than the value corresponding to a period of a half wave length corresponds to the third signal 2152 (V_(L)) leading with respect to the fourth signal 2154 (V_(RS)); and a stored value of the phase timer equal to the value corresponding to a period of a half wave length corresponds to the third signal 2152 (V_(L)) being 180 degrees out of phase with respect to the fourth signal 2154 (V_(RS)).

Referring to FIG. 114, in accordance with a sixth embodiment of a subsystem for sensing one or more variables associated with the first resonant circuit 2106, the relative phase of the third 2152 (V_(L)) and fourth 2154 (V_(RS)) signals can be measured with an apparatus comprising first 2156 and second 2158 phase-locked-loops (PLL), the respective inputs of which are operatively coupled to the respective third 2152 (V_(L)) and fourth 2154 (V_(RS)) signals, the respective outputs of which are coupled to an exclusive-OR (XOR) gate 2160, the output of which is used to control gate of a counter 2162, which counter 2162 may be incorporated in, or implemented in software by, the processor 2132. More particularly, the first phase-locked-loop 2156 (PLL) generates a first coherent square wave 2164 that is phase-aligned with the third signal 2152 (V_(L)), and the second phase-locked-loop 2158 (PLL) generates a second coherent square wave 2166 that is phase-aligned with the fourth signal 2154 (V_(RS)). The output signal 2168 of the exclusive-OR (XOR) gate 2160 is ON when the values of the first 2164 and second 2166 coherent square waves are different—corresponding to periods of associated relative phase difference,—and is OFF when the values of the first 2164 and second 2166 coherent square waves are the same. The counter 2162 is reset responsive to a positive-going leading edge of the output signal 2168, and thereafter continues to count at a fixed rate until the output signal 2168 returns to an OFF condition, at which time the associated value of the counter is stored. Accordingly, the counter 2162 measures the period of time corresponding to the phase difference of the third 2152 (V_(L)) and fourth 2154 (V_(RS)) signals. A stored counter value less than a value corresponding to a period of a half wave length corresponds to the third signal 2152 (V_(L)) lagging with respect to the fourth signal 2154 (V_(RS)); a stored counter value greater than the value corresponding to a period of a half wave length corresponds to the third signal 2152 (V_(L)) leading with respect to the fourth signal 2154 (V_(RS)); and a stored counter value equal to the value corresponding to a period of a half wave length corresponds to the third signal 2152 (V_(L)) being 180 degrees out of phase with respect to the fourth signal 2154 (V_(RS)).

Referring to FIG. 115, in accordance with a fourth embodiment of the magnetic sensor 2100.4, the capacitance C_(S) of the first capacitor 2108 (C_(S)) in the embodiments illustrated in FIG. 108 can be distributed amongst a plurality of capacitors, for example, third 2170 (C₁) and fourth 2172 (C₂) capacitors, each connected to different ends of the first coil 2042 (L₁)—i.e. so that the first coil 2042 (L₁) is connected between the third 2170 (C₁) and fourth 2172 (C₂) capacitors,—wherein the capacitances of the third 2170 (C₁) and fourth 2172 (C₂) capacitors are adapted so that the capacitance of their combination in series is equal to the capacitance C_(S) of the first capacitor 2108 (C_(S)), as follows:

$\begin{matrix} {C_{S} = \frac{C_{1} \cdot C_{2}}{C_{1} + C_{2}}} & (14) \end{matrix}$

This distribution of capacitance to both sides of the first coil 2042 (L₁) is beneficial in providing for tolerating shorts to either power or ground in the conductors that couple the first coil 2042 (L₁) to the associated electrical circuit 2102, which shorts might otherwise damage the associated electrical circuit 2102, but which instead are readily detected by the above described embodiments for sensing one or more variables associated with the first resonant circuit 2106. For example, typically the first coil 2042 (L₁) would be connected to the associated electrical circuit 2102 with a cable or wiring harness, which might be susceptible to the above described faults during assembly or operation of the vehicle 12. The resonance conditions of the first resonant circuit 2106 are otherwise as described hereinabove for a first resonant circuit 2106 incorporating a single first capacitor 2108 (C_(S)).

In accordance with a fifth embodiment of the magnetic sensor 2100.5, the resistance R_(L1) of the first coil 2042 (L₁) increases if the wire gauge thereof is reduced, or the number of turns N thereof is increased. If the resistance R_(L1) of the first coil 2042 (L₁) is sufficient to limit the maximum current I in the first resonant circuit 2106 to an acceptable level, then the resistor 2110 (R_(S)) can be eliminated from the first resonant circuit 2106. This arrangement also provides for improved sensitivity of the voltage (V_(L)) across the first coil 2042 (L₁) to changes in the resistance R_(L1) of the first coil 2042 (L₁), e.g. as might be caused by a shorting of one or more turns within the first coil 2042 (L₁); which otherwise for a system incorporating a resistor 2110 (R_(S)) in the first resonant circuit 2106, increases as the ratio of the resistance R_(L1) to the resistance R_(S) increases. For example, the intrinsic resistance of the first coil 2042 (L₁) can be set to a value between about 0.1 ohms and 10 ohms by adjusting the associated wire size (gauge) and/or length of wire (number of turns). For a first coil 2042 (L₁) of 60 turns, if the total intrinsic resistance thereof were 0.1 ohms, the resistance per turn would be 0.0001666 ohms per turn; whereas if the total intrinsic resistance were 10 ohms, the resistance per turn would be 0.16 ohms per turn, the latter of which would be substantially easier to measure. In addition to being affected by the total intrinsic resistance of the first coil 2042 (L₁), the detectability of shorted turns is also affected by resistance of the series resistor 2110 (R_(S)) in relation to that of the first coil 2042 (L₁), and can be improved by increasing the gain of the fourth amplifier 2146 used to amplify the voltage across the resistor 2110 (R_(S)).

In accordance with the above described embodiments, the oscillation frequency f₀ may be adapted to provide for a resonant or near-resonant condition at the nominal state of the vehicle 12 and the associated magnetic circuit 188 (i.e. pre-crash); or may be adapted to be off-resonance for the nominal condition of the vehicle body 168 and the associated magnetic circuit 188, and then to provide for a resonant or near-resonant condition responsive to a crash, as a result of an associated shift in the inductance L₁′ or L₂′ of the first coil 2042 (L₁) or the second coil 2054 (L₂). Furthermore, the magnetic sensor 2100 could incorporate a plurality of distinct frequencies, different frequencies being adapted to provide for an associated resonance for different associated conditions of the vehicle body 168.

Referring to FIG. 108, in accordance with a sixth embodiment of the magnetic sensor 2100.6, the oscillator 2104 may be adapted to be controllable responsive to a signal 2174 from the processor 2132. For example, the oscillator 2104 may be a voltage controlled oscillator (VCO). In operation, the oscillation frequency f₀ of the oscillator 2104 is swept through—in either a stepwise or continuous fashion—the associated resonant frequency f_(n) of the first resonant circuit 2106. An output from the oscillator can be coupled to the processor 2132, either directly, or, if analog, through a fifth analog-to-digital converter 2176, so as to provide a measure of, the output from the oscillator, for example, the oscillation frequency f₀ or associated level V of the first signal 2044. For example, the processor 2132 could directly sense the first signal 2044, and then determine the associated level V and oscillation frequency f₀ directly therefrom. The particular resonant frequency can then be identified as the oscillation frequency f₀ for which the voltage across either the first coil 2042 (L₁), the first capacitor 2108 (C_(S)) or the resistor 2110 (R_(S)) is maximized, and the associated inductance L₁′ of the first coil 2042 (L₁) can be identified therefrom. Similarly, the associated inductance L₂′ of the second coil 2054 (L₂) can be identified after determining by similar means the resonant frequency f_(n) _(—) ₂ of the second resonant circuit 2116.

The particular operating point on the frequency response characteristic—e.g. as illustrated in FIG. 110—of the first resonant circuit 2106 will affect the amount of power transferred to the magnetic circuit 188 by the oscillator 2104/first buffer amplifier 2112. In one embodiment, upon initialization of the magnetic sensor 2100, the resonant frequency of the first resonant circuit 2106 and the nature of the associated frequency response is identified by sweeping the oscillation frequency and monitoring the response from the associated magnetic sensing element 2050, generally as described hereinabove, either using the primary oscillator 2104 as the signal source, or another oscillator, so as to provide for measuring both the resonant frequency of the first resonant circuit 2106, and its associated frequency response. If the resulting measured resonant frequency is different from the nominal oscillation frequency f₀ of the oscillator 2104, then thereafter, when operating at the nominal oscillation frequency f₀, one or more software or hardware parameters or variables would be adjusted, e.g. in accordance with a correction factor, to accommodate the associated degradation in gain caused by operating with an oscillation frequency f₀ that differs from the resonant frequency of the associated first resonant circuit 2106. Accordingly, this embodiment provides for adapting to relatively long term changes in the magnetic sensor 2100, for example, as might result from either production variability, temperature, or aging. A warning can be generated or activated, e.g. via an indicator or alarm, if the magnitude of the associated correction factor exceeds a threshold, e.g. indicative of the need for maintenance or repair.

For example, if the first coil 2042 (L₁) were an ideal inductor having an inductance of L₁, then if the resonant frequency were determined to be f_(n), then the inductance L₁ would be given by:

$\begin{matrix} {L_{1} = \frac{1}{4 \cdot \pi^{2} \cdot f_{n}^{2} \cdot C_{S}}} & (15) \end{matrix}$

In accordance with another aspect of the sixth embodiment, either the oscillator 2104 or an associated amplifier, e.g. the first buffer amplifier 2112, may be controlled responsive to a signal 2174 from the processor 2132, or another controller, so as to control the level of current I to the first coil 2042 (L₁), as sensed from the voltage V_(RS) across the resistor 2110 (R_(S)). By operating at least near resonance, the impedance of the first resonant circuit 2106 is at least substantially resistive, which simplifies the associated control algorithm for controlling the level of current I. For example, the current I may be controlled to a constant value using a relatively low bandwidth control algorithm which is fast enough so as to correct for long term variations, e.g. resulting from production variations, temperature effects, or aging, but is slow enough so as to not adversely affect a crash induced perturbation or variation of the current I. Accordingly, this closed loop current control system provides for maintaining the nominal level of current I through the first coil 2042 (L₁) so as to correspondingly maintain an associated nominal level of magnetic flux 186, φ in the associated magnetic circuit 188, thereby accommodating changes to the first resonant circuit 2106 that might affect the resonant frequency thereof, and accordingly, might otherwise adversely affect the level of current I as a result of the inherent frequency response of the first resonant circuit 2106 and its associated bandwidth.

Responsive to the detection of a crash, or other condition affecting the vehicle body 168 or associated magnetic circuit 188, or responsive to the detection of a failure of a component of the magnetic sensor 2100, by any of the above described embodiments, the processor 2132 can then either actuate an associated safety restraint actuator 110, or an associated indicator 2178, as necessary to either protect or inform an occupant of the vehicle 12.

Referring to FIG. 116, the current I in the first coil 2042 may be used to provide a measure of the opening angle α of the door 78 as a result of the affect thereof on the reluctance of the associated magnetic circuit 188. Alternatively, or in addition to this measure, the opening angle α of the door 78 may be detected by providing a third coil 2180 operatively coupled to the door 78, which cooperates with the first coil 2042 operatively coupled to a relatively fixed portion of the vehicle 12, e.g. about the axis 2182 of a fixed portion of a door hinge 2018. For example, the third coil 2180 could be located about an axis 2184 that rotates with the door 78, e.g. an axis of a moveable portion of a hinge 2018. The third coil 2180 is located either in the near field of the first coil 2042, or in the associated magnetic circuit 188 so as to be rotatable in relation to the direction of the magnetic flux 186, φ therein, so that a signal from the third coil 2180 is responsive to the magnetic flux 186, φ generated by the first coil 2042 responsive to a current I applied thereto, and is responsive to the mutual coupling of the magnetic flux 186, φ between the first 2042 and third 2180 coils. This mutual coupling is responsive to the alignment between the first 2042 and third 2180 coils, which depends upon the opening angle α of the door 78. A signal from the third coil 2180 can provide a measure of whether the door 78 is open and/or a measure of the associated opening angle α. The third coil 2180 can also be used a sense coil 2062 as described hereinabove, which can provide an indication of the operativeness of the first coil 2042. The third coil 2180 can also be used as a sensor in a feedback control system (e.g. an automatic gain control (AGC)) which is adapted to control the level of magnetic flux 186, φ generated by the first coil 2042, which can also be adapted so that one or more signals from the associated control system provide either a measure of the door opening status or angle α, or a measure of energy flow responsive to a crash, or both.

Referring to FIG. 117, in accordance with another embodiment, a vehicle 12 incorporates a magnetic crash sensing system 2200 comprising first 2202 and second 2204 magnetic sensors operatively associated with the left 2206 and right 2208 sides of the vehicle 12, respectively.

The first magnetic sensor 2202 comprises an associated oscillator 2210.1 operatively coupled to an associated coil driver 2212.1 which is operatively coupled to an associated first resonant circuit 2214.1 comprising an associated first coil 2216.1 in series with an associated first capacitor 2218.1, wherein the associated first coil 2216.1 is located at an associated first location 2220.1 on an associated magnetic circuit 2222.1 thereof. The first magnetic sensor 2202 further comprises an associated magnetic sensing element 2224.1 comprising, for example, an associated second coil 2224.1′, which is illustrated as part of a second resonant circuit 2226.1 further comprising a second capacitor 2228.1 in parallel with the second coil 2224.1′. The associated magnetic sensing element 2224.1 is located at an associated second location 2230.1 on the associated magnetic circuit 2222.1. For example, the first 2220.1 and second 2230.1 locations respectively are illustrated as respectively comprising a hinge 2018 and a striker 170 of a door 78 on the left side 2206 of the vehicle 12. The output of the second resonant circuit 2226.1 is amplified/buffered by an associated first amplifier 2232.1, e.g. a differential amplifier, the output of which is processed by an associated preprocessing circuit 2234.1, for example, comprising elements comparable to the first amplifier 2122, first coupling capacitor 2124, first demodulator 2126, second coupling capacitor 2134, second amplifier 2128, and third amplifier 2136 as illustrated in FIG. 108 and described hereinabove. The output of the associated preprocessing circuit 2234.1 is converted to digital form by at least one associated first analog-to-digital converter 2236.1, and the signal therefrom input to an associated processor 2238.

The second magnetic sensor 2204 comprises an associated oscillator 2210.2 operatively coupled to an associated coil driver 2212.2 which is operatively coupled to an associated first resonant circuit 2214.2 comprising an associated first coil 2216.2 in series with an associated first capacitor 2218.2, wherein the associated first coil 2216.2 is located at an associated first location 2220.2 on an associated magnetic circuit 2222.2 thereof. The second magnetic sensor 2204 further comprises an associated magnetic sensing element 2224.2 comprising, for example, an associated second coil 2224.2′, which is illustrated as part of a second resonant circuit 2226.2 further comprising a second capacitor 2228.2 in parallel with the second coil 2224.2′. The associated magnetic sensing element 2224.2 is located at an associated second location 2230.2 on the associated magnetic circuit 2222.2. For example, the first 2220.2 and second 2230.2 locations respectively are illustrated as respectively comprising a hinge 2018 and a striker 170 of a door 78 on the right side 2208 of the vehicle 12. The output of the second resonant circuit 2226.2 is amplified/buffered by an associated first amplifier 2232.2, e.g. a differential amplifier, the output of which is processed by an associated preprocessing circuit 2234.2, for example, comprising elements comparable to the first amplifier 2122, first coupling capacitor 2124, first demodulator 2126, second coupling capacitor 2134, second amplifier 2128, and third amplifier 2136 as illustrated in FIG. 108 and described hereinabove. The output of the associated preprocessing circuit 2234.2 is converted to digital form by at least one associated first analog-to-digital converter 2236.2, and the signal therefrom input to the processor 2238.

The first 2202 and second 2204 magnetic sensors, as described heretofore, are adapted to each individually function in cooperation with the corresponding left 2206 and right 2208 sides of the vehicle 12 in accordance with any of the earlier described embodiments of magnetic sensors, for example, as identified by magnetic sensors 2010, 2100, 2100.1, 2100.2, 2100.3, 2100.4, 2100.5, 2100.6.

Furthermore, the oscillation frequency f₁ of the oscillator 2210.1 associated with the first magnetic sensor 2202 is adapted to be different from the oscillation frequency f₂ associated with the oscillator 2210.2 of the second magnetic sensor 2204, so that the signals from the corresponding first coils 2216.1 and 2216.2 can be differentiated from one another, to the extent that the magnetic circuits 2222.1, 2222.2 associated with the first coils 2216.1, 2216.2 associated with one magnetic sensor 2202, 2204 interact with the magnetic sensing elements 2224.2, 2224.1 associated with the other magnetic sensor 2204, 2202. For example, in one embodiment, the oscillation frequency f₁ of the oscillator 2210.1 associated with the first magnetic sensor 2202 is about 10 KHz, whereas the oscillation frequency f₂ associated with the oscillator 2210.2 of the second magnetic sensor 2204 is about 20 KHz. It may be beneficial for the respective oscillation frequencies f₁ and f₂ to be adapted so that one is not a harmonic of the other, for example, so that the oscillation frequencies f₁ and f₂ are relatively indivisible or irrational with respect to one another, so as to preclude the prospect of a harmonic of a signal generated by one magnetic sensor 2202, 2204 being interpreted as originating from the other magnetic sensor 2204, 2202.

The first magnetic sensor 2202 further comprises an associated third resonant circuit 2240.1, e.g. comprising a series combination of an associated inductor 2242.1 (e.g. a third coil 2242.1′) and a third capacitor 2244.1. The third resonant circuit 2240.1 further comprises an associated current sensor 2246.1, for example an associated series resistor 2248.1 and an associated second amplifier 2250.1, e.g. a differential amplifier, adapted to measure the voltage across the associated series resistor 2248.1. The current sensor 2246.1 may be embodied in other ways, for example by measuring the voltage across either the associated inductor 2242.1 or the associated third capacitor 2244.1, or by measuring a magnetic field generated by the current flowing in the associated third resonant circuit 2240.1. The third resonant circuit 2240.1 is adapted to have a resonant frequency f_(3.1) that is substantially equal to the oscillation frequency f₂ associated with the oscillator 2210.2 of the second magnetic sensor 2204. The output of the associated current sensor 2246.1, e.g. the output of the associated second amplifier 2250.1, is operatively coupled to a second analog-to-digital converter 2252.1, and the output therefrom is operatively coupled to the processor 2238.

Furthermore, the second magnetic sensor 2204 further comprises an associated third resonant circuit 2240.2, e.g. comprising a series combination of an associated inductor 2242.2 (e.g. a third coil 2242.2′) and a third capacitor 2244.2. The third resonant circuit 2240.2 further comprises an associated current sensor 2246.2, for example an associated series resistor 2248.2 and an associated second amplifier 2250.2, e.g. a differential amplifier, adapted to measure the voltage across the associated series resistor 2248.2. The current sensor 2246.2 may be embodied in other ways, for example by measuring the voltage across either the associated inductor 2242.2 or the associated third capacitor 2244.2, or by measuring a magnetic field generated by the current flowing in the associated third resonant circuit 2240.2. The third resonant circuit 2240.2 is adapted to have a resonant frequency f_(3.2) that is substantially equal to the oscillation frequency f₁ associated with the oscillator 2210.1 of the first magnetic sensor 2202. The output of the associated current sensor 2246.2, e.g. the output of the associated second amplifier 2250.2, is operatively coupled to a second analog-to-digital converter 2252.2, and the output therefrom is operatively coupled to the processor 2238.

The magnetic circuit 2222.1 associated with the first coil 2216.1 of the first magnetic sensor 2202 includes both second locations 2230.1 and 2230.2 respectively associated with the first 2202 and second 2204 magnetic sensors respectively. Similarly, the magnetic circuit 2222.2 associated with the first coil 2216.2 of the second magnetic sensor 2204 includes both second locations 2230.2 and 2230.1 respectively associated with the second 2204 and first 2202 magnetic sensors respectively. Accordingly, magnetic flux 186, φ generated by the first coil 2216.1 of the first magnetic sensor 2202 is sensed by the magnetic sensing element 2224.2 of the second magnetic sensor 2204, and magnetic flux 186, φ generated by the first coil 2216.2 of the second magnetic sensor 2204 is sensed by the magnetic sensing element 2224.1 of the first magnetic sensor 2202. The third resonant circuits 2240.1, 2240.2 are series resonant, and accordingly, have a minimum resistance at their respective resonant frequencies f_(3.1), f_(3.2), so that the frequency response of current therethrough exhibits a maximum a the respective resonant frequencies f_(3.1), f_(3.2). Stated in another way, each third resonant circuit 2240.1, 2240.2 acts as a current sink at its respective resonant frequency f_(3.1), f_(3.2), and a measure of current therethrough provides a measure of the magnitude of an associated frequency component of the magnetic flux 186, φ, having the corresponding resonant frequency f_(3.1), f_(3.2), that is sensed by the corresponding first coil 2216.1, 2216.2. Accordingly, the current sensed by the current sensor 2246.1 associated with the first magnetic sensor 2202 provides a measure of the operativeness and operation of the first coil 2216.2 associated with the second magnetic sensor 2204, and the current sensed by the current sensor 2246.2 associated with the second magnetic sensor 2204 provides a measure of the operativeness and operation of the first coil 2216.1 associated with the first magnetic sensor 2202, so that each magnetic sensor 2202, 2204 can be used to verify the operation of the other, and thereby provide a measure for safing the other magnetic sensor 2204, 2202.

Responsive to a first measure of operativeness of the first coil 2216.1 associated with the left side 2206 of the vehicle 12—which first measure of operativeness is responsive a signal from the current sensor 2246.2 associated with the third resonant circuit 2240.2 associated with the second magnetic sensor 2204 associated with the right side 2208 of the vehicle 12—the processor 2238 provides for disabling a first safety restraint actuator 2254.1 associated with the left side 2206 of the vehicle 12 if the first measure of operativeness indicates that the first coil 2216.1 is inoperative. Otherwise, if the first magnetic sensor 2202 is otherwise operative, then the first safety restraint actuator 2254.1 associated with the left side 2206 of the vehicle 12 is actuated responsive to a signal from the associated magnetic sensing element 2224.1 associated with the first magnetic sensor 2202 associated with the left side 2206 of the vehicle 12.

Responsive to a second measure of operativeness of the first coil 2216.2 associated with the right side 2208 of the vehicle 12—which second measure of operativeness is responsive a signal from the current sensor 2246.1 associated with the third resonant circuit 2240.1 associated with the first magnetic sensor 2202 associated with the left side 2206 of the vehicle 12—the processor 2238 provides for disabling a second safety restraint actuator 2254.2 associated with the right side 2208 of the vehicle 12 if the second measure of operativeness indicates that the first coil 2216.2 is inoperative. Otherwise, if the second magnetic sensor 2204 is otherwise operative, then the second safety restraint actuator 2254.2 associated with the right side 2208 of the vehicle 12 is actuated responsive to a signal from the associated magnetic sensing element 2224.2 associated with the second magnetic sensor 2204 associated with the right side 2208 of the vehicle 12.

Referring again to FIG. 108, the first resonant circuit 2106 of the third embodiment of the magnetic sensor 2100.3 need not necessarily be operated at resonance or near resonance. The first resonant circuit 2106 is illustrated in FIG. 108 as comprising a first embodiment of a series LC circuit 2300.1, which comprises the first coil 2042 (L₁) in series with the first capacitor 2108 (C_(S)). Although the first resonant circuit 2106 exhibits a resonant frequency ω_(n) at which the associated impedance Z thereof is minimized and is real valued, the first resonant circuit 2106 need not necessarily be operated at its resonant frequency ω_(n), but may alternatively be operated at a frequency X that is different from the resonant frequency ω_(n), for example, either higher or lower than the resonant frequency ω_(n), for example, lower than the resonant frequency ω_(n) so that the first coil 2042 is dominated by inductive effects. At any frequency ω, the capacitive reactance of the first capacitor 2108 (C_(S)) will at least partially cancel the nominal inductive reactance of the first coil 2042 so that the associated changes in the inductive reactance of the first coil 2042 responsive to changes in the associated magnetic circuit 188 will be increased thereby in proportion to the total impedance of the series LC circuit 2300.1, so as to provide for a greater dynamic range and a finer resolution of detection of the associated changes to the resulting signal responsive to changes in the associated magnetic circuit 188.

For example, referring to FIGS. 118 a and 118 b, the impedance of various elements of the series LC circuit 2300.1 is respectively plotted and tabulated for various operating conditions, showing that a reduction in the net nominal reactance of the series LC circuit 2300.1 provides for increasing the sensitivity of the net impedance thereof to changes in reactance or resistance of the elements of the series LC circuit 2300.1. In each of the examples, a hypothetical first coil 2042 (L₁) is assumed to have a hypothetical nominal resistance R_(L) of 3 ohms, and is fed with a first signal 2044 at a nominal frequency X so that the corresponding hypothetical nominal inductive reactance is 1000 ohms. FIG. 118 a is a polar plot with logarithmic scales, wherein each impedance value is represented as a vector, the magnitude of which is the magnitude of the impedance Z, i.e. |Z|, is given by: and the phase angle θ of which from the abscissa is given by: |Z|=√{square root over (X _(Z) ² +R ²)}  (16)

and the phase angle θ of which from the abscissa is given by:

$\begin{matrix} {\theta = {\tan^{- 1}\left( \frac{X_{Z}}{R} \right)}} & (17) \end{matrix}$ where X_(Z) is the net reactance of the series LC circuit 2300.1—positive for net inductance, negative for net capacitance,—and R is the resistance of the series LC circuit 2300.1, i.e. the resistance R_(L) of the first coil 2042 (L₁).

In the table of FIG. 118 b, the nominal values of resistance R, reactance X_(Z), and impedance Z are indicated therein as R₀, X₀, and Z₀ respectively, wherein the impedance vectors 2302, 2304, 2306, 2308 are plotted in FIG. 118 a for nominal reactances X_(Z) of +1000, +100, +10 and 0 ohms respectively, in combination with a nominal resistance R_(L) of 3 ohms, the data for which is tabulated in rows ## 1-4, 5-8, 10-13 and 15 of the table of FIG. 118 b. Accordingly, the nominal resistance R_(L) of 3 ohms shifts the net impedance Z from a pure inductive reactance X_(L) by 0.17 degrees, 1.72 degrees, 26.7 degrees, respectively, for the respective cases of 1000, 100, and 10 ohms of net inductive reactance X_(L), respectively. Given these nominal conditions, and additionally, the nominal condition of 5 ohms of inductive reactance X_(L) in combination with a nominal resistance R_(L) of 3 ohms indicated in rows ## 4, 9 and 14 of the table of FIG. 118 b, the sensitivity of the change ΔZ in net impedance Z, expressed as a percentage in the column labeled ΔZ/Z %, and the change Δθ in phase angle θ, expressed in degrees in the column labeled Δθ, is tabulated for various changes ΔR in the resistance R_(L), and ΔX in the inductive reactance X_(L), respectively, relative to the respective nominal values R₀ and X₀. Accordingly, rows ## 1-5 of the table of FIG. 118 b show the impedance sensitivity ΔZ/Z and change Δθ in phase angle θ for each of the above described nominal conditions responsive to an increase in inductive reactance X_(L) in the amount of 5 ohms; rows ## 6-10 show the impedance sensitivity ΔZ/Z and change Δθ in phase angle θ for each of the above described nominal conditions responsive to an decrease in resistance R in the amount of 1 ohm, i.e. as might be responsive to associated eddy current affects; and rows ## 11-15 show the impedance sensitivity ΔZ/Z and change Δθ in phase angle θ for each of the above described nominal conditions responsive to a combined increase in inductive reactance X_(L) in the amount of 5 ohms and decrease in resistance R in the amount of 1 ohm. Accordingly, a decrease in the net nominal reactance X_(Z) leads to a corresponding increase in impedance sensitivity ΔZ/Z and a corresponding increase in the change Δθ in phase angle θ, responsive to a given change in either reactance R or resistance R of the associated series LC circuit 2300.1. Assuming a hypothetical nominal inductive reactance X_(L) of 1000 ohms, the associated above-described reductions in inductive reactance X_(L) to values of 100, 10 and 0 ohms respectively are achieved by adapting the series capacitance C_(S) of the first capacitor 2108 (C_(S)) of the series LC circuit 2300.1 so that the respective corresponding capacitive reactance X_(C) is 900, 990 and 1000 ohms, respectively. For example, a capacitive reactance X_(C) of 1000 ohms, indicated by the impedance vector 2310 in FIG. 118 a, provides for a nominally resonant condition, as indicated by the net impedance vector 2308 in FIG. 118 a and rows ## 5, 10 and 15 of table of FIG. 118 b; and, relative to the resonant condition, the impedance vector resulting from an increase in inductive reactance X_(L) by an amount of 5 ohms, corresponding to row # 5 of table of FIG. 1184 b, is illustrated by the corresponding impedance vector 2312 in FIG. 118 a, which illustrates an increase in phase angle θ of about 59 degrees relative to the resonant condition. Accordingly, the cancellation of some or all of the inductive reactance of the first coil 2042 (L₁), using a series capacitance C_(S) of a first capacitor 2108 (C_(S)) in series with the first coil 2042 (L₁) in a series LC circuit 2300.1, can beneficially increase the sensitivity of the resulting net impedance Z, and can increase the change the associated phase angle θ, responsive to changes in the magnetic circuit 188 associated with the first coil 2042 (L₁), for example, responsive to a crash that affects the magnetic circuit 188. The associated electrical circuit 2102, for example, the demodulator 2144 thereof, may be adapted so as to provide for detecting in-phase and quadrature-phase signals responsive to, and as measures of, the current I through the first coil 2042, so as to provide for detecting these associated changes in the net impedance of the series LC circuit 2300.1, for example, as disclosed in U.S. Provisional Application Ser. No. 60/892,241, which was filed on 28 Feb. 2007, and which is incorporated herein by reference. For example, FIGS. 46-50 and 53, and the associated text of U.S. Provisional Application Ser. No. 60/892,241 disclose an example of one particular type of demodulator 2144 that may be used. Furthermore, for example, in any of the embodiments illustrated in U.S. Provisional Application Ser. No. 60/892,241, any of the coils 14, 72 used for generating and sensing the associated magnetic fields may be replaced by a corresponding series LC circuit 2300, so as to provide for reducing the net nominal reactance thereof at the operating frequency so as to provide for enhancing the impedance sensitivity ΔZ/Z and changes Δθ in phase angle θ of the series LC circuit 2300.2 responsive to changes in either the inductance L or the effective resistance R thereof, responsive to changes in the associated magnetic circuit 188, for example, responsive to a crash-induced changes to the magnetic circuit 188.

Similarly, in the fourth embodiment of the magnetic sensor 2100.4 illustrated in FIG. 115, wherein the third 2170 (C₁) and fourth 2172 (C₂) capacitors in series with the first coil 2042 (L₁) constitute a second embodiment of a series LC circuit 2300.2, the net series capacitive reactance X_(C) of the third 2170 (C₁) and fourth 2172 (C₂) capacitors in the series LC circuit 2300.2 may be used to at least partially cancel the nominal inductive reactance X_(L) of the first coil 2042 (L₁)—or, as first described hereinabove, to substantially fully cancel the nominal inductive reactance X_(L) of the first coil 2042 (L₁) so as to provide for a resonant mode of operation—so as to provide for enhancing the impedance sensitivity ΔZ/Z and changes Δθ in phase angle θ of the series LC circuit 2300.2 responsive to changes in the inductance L or effective resistance R thereof, responsive to changes in the associated magnetic circuit 188, for example, responsive to a crash-induced changes to the magnetic circuit 188.

In a practical magnetic sensor 2100 incorporating a series LC circuit 2300, the associated first coil 2042 (L₁) is subject to tolerance, i.e. part-to-part variation, and variation in the inductance L, thereof over time, or responsive to operating conditions. Furthermore, the associated capacitance(s) C of the first capacitor 2108 (C_(S)), or the third 2170 (C₁) and fourth 2172 (C₂) capacitors, may be practically limited to a specific set of available values, i.e. those which are available in production parts. Yet further, there may be a preferred inductance L₁ of the first coil 2042 (L₁) so as to provide for cooperation of the first coil 2042 (L₁) with the associated magnetic circuit 188 to be sensed.

Referring to FIG. 119, in accordance with a first aspect of in impedance adaptation circuit 2314.1, a seventh embodiment of a magnetic sensor 2100.7 incorporates a third embodiment of a series LC circuit 2300.3 comprising a series combination of a first capacitor 2170 (C₁), the first coil 2042 (L₁), and a second inductor 2316 (L₂), wherein the inductance L₁ of the first coil 2042 (L₁) is selected on the basis of it operation as an associated magnetic sensing element in cooperation with the associated magnetic circuit 188; the first capacitor 2170 (C₁) is selected from an available set of capacitance values of available capacitors so as to provide for a particular nominal impedance characteristic of the series LC circuit 2300.3 in combination with the remaining elements of the series LC circuit 2300.3; and the inductance L₂ of the second inductor 2316 (L₂) is chosen to provide for the particular nominal impedance characteristic of the series LC circuit 2300.3 in combination with the remaining elements of the series LC circuit 2300.3. For example, in one set of embodiments, the nominal impedance characteristic is a resonance condition, wherein the net nominal reactance of the series LC circuit 2300.3 is substantially zero. In another set of embodiments, the net nominal reactance of the series LC circuit 2300.3 exhibits a reactance X—either inductive X_(L) or capacitive X_(C),—the magnitude of which is substantially less than the nominal inductive reactance X_(L1) of the first coil 2042 (L₁) alone. As another example, the inductance L₂ of the second inductor 2316 (L₂) could be either selected or adapted after measuring the nominal inductance L₁ of the first coil 2042 (L₁), for example, during production of the associated magnetic sensor 2100.7.

The first coil 2042 (L₁) is located so as to be magnetically coupled to the associated magnetic circuit 188 to be sensed by the magnetic sensor 2100.7. In one set of embodiments, the first capacitor 2170 (C₁) and second inductor 2316 (L₂) are located in the associated electrical circuit 2102 of the magnetic sensor 2100.7, for example, in the circuitry of an associated electronic module, for example, to which the first coil 2042 (L₁) might be coupled with an associated cable of a wiring harness. Alternatively, one or both of the first capacitor 2170 (C₁) and second inductor 2316 (L₂) could be co-located with the first coil 2042 (L₁), or could be separately located.

The third embodiment of the series LC circuit 2300.3 also provides for reducing the necessary capacitance of the associated first capacitor 2170 (C₁) for a given nominal impedance characteristic of the series LC circuit 2300.3. For example, this can be seen for a magnetic sensor 2100.7 with a nominal impedance characteristic that is a resonance condition, wherein the associated resonant frequency ω is given by ω=1/√(LC), and for a given resonant frequency c, as the total inductance L is increased, for example, by adding the second inductor 2316 (L₂) in series with the first coil 2042 (L₁), then the associated capacitance C would be decreased in order to maintain the given resonant frequency ω. Accordingly, the third embodiment of a series LC circuit 2300.3 provides for independently selecting the capacitance value of the first capacitor 2170 (C₁) and the inductance L, of the first coil 2042 (L₁) so as to possibly reduce the cost of the associated magnetic sensor 2100.7 for a given level of sensing performance. For example, relatively smaller commercial production capacitors may be relatively cheaper, or exhibit relatively less variability, than relatively larger commercial production capacitors, all else being equal.

Referring to FIG. 120, in accordance with a second aspect of in impedance adaptation circuit 2314.2, an eighth embodiment of a magnetic sensor 2100.8 incorporates a fourth embodiment of a series LC circuit 2300.4 comprising at least one of a fixed or adjustable capacitance 2318 (C_(X)) and a fixed or adjustable inductance 2320 (L_(x)), in series with the first coil 2042 (L₁) and with one another if both are incorporated, wherein the inductance L, of the first coil 2042 (L₁) is selected on the basis of it operation as an associated magnetic sensing element in cooperation with the associated magnetic circuit 188, and the adjustable capacitance 2318 (C_(X)) and the adjustable inductance 2320 (L_(X)), if incorporated, are under control of an associated processor 2132, so as to provide for selecting or controlling one or both of the capacitance C_(X) of the adjustable capacitance 2318 (C_(X)) and the inductance L_(X) of the adjustable inductance 2320 (L_(X)).

For example, referring to FIG. 121, in one embodiment, the adjustable capacitance 318 (C_(X)) of the fourth embodiment of the series LC circuit 2300.4 is implemented with a switched capacitor circuit 2322 comprising a nominal bias capacitor C* in parallel with N capacitive tuning elements 2324.0-2324.N, wherein N is greater than or equal to zero. Each capacitive tuning element 2324.i comprises a tuning capacitor C_(i) in series with a corresponding controllable switching element 2326.i, for example, an FET transistor as illustrated, that is operatively coupled to, and under control of the processor 2132, wherein the index i ranges from 0 to N, and when the controllable switching element 2326.i is activated, the capacitance of the associated tuning capacitor C_(i) is added into the capacitance 2318 (C_(X)) of the adjustable capacitance 2318 (C_(X)). For example, in one embodiment, the values of the associated tuning capacitors C₀-C_(N) are determined by a binary geometric progression, so that the value of the i^(th) tuning capacitor C_(i) is substantially equal to 2^(i) times the value of the 0^(th) tuning capacitor C₀, so as to provide for collectively selecting any capacitance value between 0 and (2^(N+1)−1)·C₀ in increments of C₀. Furthermore, the switched capacitor circuit 2322 may incorporate a controllable switching element 2326*, for example, an FET transistor as illustrated, in parallel with the nominal bias capacitor C* and under control of the processor 2132, so as to provide for shorting the switched capacitor circuit 2322 and thereby setting the adjustable capacitance 2318 (C_(X)) to a value that is substantially equal to zero, so as to effectively remove the adjustable capacitance 2318 (C_(X)) from the series LC circuit 2300.4.

Furthermore, referring to FIG. 122, in one embodiment, the adjustable inductance 2320 (L_(X)) of the fourth embodiment of the series LC circuit 2300.4 is implemented with a switched inductor circuit 2328 comprising a nominal bias inductor L* in parallel with M inductive tuning elements 2324.0-2326.M, wherein M is greater than or equal to zero, and each inductive tuning element 2330.i comprises a tuning inductor L_(i) in parallel with a corresponding controllable switching element 2332.i, for example, an FET transistor as illustrated, that is operatively coupled to, and under control of the processor 2132, wherein the index i ranges from 0 to M, and when the controllable switching element 2332.i is activated, the inductance of the associated tuning inductor L_(i) is not added into the inductance 2320 (L_(X)) of the adjustable inductance 2320 (L_(X)). For example, in one embodiment, the values of the associated tuning inductors L₀-L_(M) are determined by a binary geometric progression, so that the value of the i^(th) tuning inductor L_(i) is substantially equal to 2^(i) times the value of the 0^(th) tuning inductor L₀, so as to provide for collectively selecting any inductance value between 0 and (2^(M+1)−1)·L₀ in increments of L₀. Furthermore, the switched inductor circuit 2328 may incorporate a controllable switching element 2332*, for example, an FET transistor as illustrated, in parallel with the nominal bias inductor L* and under control of the processor 2132, so as to provide for shorting the nominal bias inductor L* when the controllable switching element 2332* is activated, thereby setting the adjustable inductance 2320 (L_(X)) to a value given by the series combination of the inductive tuning elements 2324.0-2326.M, or a value that is substantially equal to zero when each of the controllable switching elements 2332.0-2332.M is activated, so as to effectively remove the adjustable inductance 2320 (L_(X)) from the series LC circuit 2300.4.

Accordingly, in accordance with the second aspect of the impedance adaptation circuit 2314.2, as embodied in the eighth embodiment of a magnetic sensor 2100.8, the fixed or adjustable capacitance 2318 (C_(X)) and the fixed or adjustable inductance 2320 (L_(X)), either individually alone, or in combination with one another, may be used to adjust the nominal impedance of the associated fourth embodiment of the series LC circuit 2300.4, so as to either compensate for variation in the associated inductance L₁ of the first coil 2042 (L₁), or to provide for determining the inductance L₁ of the first coil 2042 (L₁).

For example, the inductance L, of the first coil 2042 (L₁) would typically be subject to part-to-part variability, and possibly variability over time. For operation of a series LC circuit 2300.4 with a nominal resonant impedance characteristic, the capacitance C_(X) of the adjustable capacitance 2318 (C_(X)), and/or the inductance L_(X) of the adjustable inductance 320 (L_(X)) may be adjusted under nominal conditions so as to substantially cancel the inductive reactance X_(L1) of the first coil 2042 (L₁), so as to provide for a substantially resonant series LC circuit 2300.4. The particular values of the adjustable capacitance 2318 (C_(X)), and/or the inductance L_(X) of the adjustable inductance 2320 (L_(X)) will depend upon the particular inductance L₁ of the first coil 2042 (L₁) at the time of compensation, which, for example, might be done when the vehicle 12 is first activated, i.e. at a “key-on” condition, so as to provide for compensating for both part-to-part variability, and variability of a given part over time. As with the seventh embodiment of the magnetic sensor 2100.7, the adjustable inductance 2320 (L_(X)) of the eighth embodiment of a magnetic sensor 2100.8 provides for utilizing relatively smaller, relatively less expensive or relatively less variable, capacitors C*, C₁-C_(N) in the associated fixed or adjustable capacitance 2318 (C_(X)). Generally, the second aspect of the impedance adaptation circuit 2314.2, as embodied in the eighth embodiment of a magnetic sensor 2100.8, provides for using relatively wider tolerance (e.g. 20% tolerance instead of 1% tolerance), lower cost parts, in the associated electronic circuitry.

As another example, the second aspect of the impedance adaptation circuit 2314.2, as embodied in the eighth embodiment of a magnetic sensor 2100.8, may be used to determine the inductance L₁ of the first coil 2042 (L₁), for example, by adjusting either or both the capacitance C_(X) of the adjustable capacitance 2318 (C_(X)), and/or the inductance L_(X) of the adjustable inductance 2320 (L_(X)), until a particular impedance condition—for example, a resonant condition—is achieved, wherein the then known values of the capacitance C_(X) of the adjustable capacitance 2318 (C_(X)), and/or the inductance L_(X) of the adjustable inductance 2320 (L_(X)), in combination with the known operating frequency ω, can then be used to determine a measure of the inductance L₁ of the first coil 2042 (L₁). In this application, the relative precision of the associated capacitors C*, C₁-C_(N) and inductors L*, L₁-L_(M), and the relative precision of the frequency ω setting, would then determine the relative accuracy of the associated resulting measure of the inductance L₁ of the first coil 2042 (L₁). Alternatively, instead of determining the inductance L₁ of the first coil 2042 (L₁) per se, the particular capacitance C_(X) of the adjustable capacitance 2318 (C_(X)), and/or the inductance L_(X) of the adjustable inductance 2320 (L_(X)) could be used to establish a threshold for detecting changes to the inductance L₁ of the first coil 2042 (L₁), for example, for purposes of establishing a detection threshold for use in detecting a crash or in controlling the actuation of a safety restraint actuator 110 responsive thereto.

As with the seventh embodiment of the magnetic sensor 2100.7, in the eighth embodiment of a magnetic sensor 2100.8, the first coil 2042 (L₁) is located so as to be magnetically coupled to the associated magnetic circuit 188 to be sensed by the magnetic sensor 2100.7. In one set of embodiments, the capacitors C*, C₁-C_(N) and inductors L*, L₁-L_(M) are located in the associated electrical circuit 2102 of the magnetic sensor 2100.8, for example, in the circuitry of an associated electronic module, for example, to which the first coil 2042 (L₁) might be coupled with an associated cable of a wiring harness. Alternatively, some or all of the capacitors C*, C₁-C_(N) and inductors L*, L₁-L_(M) could be co-located with the first coil 2042 (L₁), or could be separately located.

It should be understood that the above described embodiments, although described separately herein, can be combined with one another as additional embodiments of the magnetic sensor 2100. The sensitivity of the magnetic sensor 2100 to crashes, or other detectable events, can be set to a desired level by adjusting gain and/or threshold values associated therewith. Furthermore, in addition crash sensing and safing, the above described embodiments—when incorporating a magnetic circuit 188 involving a door 78—can be used to detect the state of opening (i.e. open or closed) of the door 78, either responsive to the self inductance of the first coil 2042, or responsive to a second signal 2114 from an associated magnetic sensing element 2050/second coil 2054.

While specific embodiments have been described in detail, those with ordinary skill in the art will appreciate that various modifications and alternatives to those details could be developed in light of the overall teachings of the disclosure. It should be understood, that any reference herein to the term “or” is intended to mean an “inclusive or” or what is also known as a “logical OR”, wherein the expression “A or B” is true if either A or B is true, or if both A and B are true. Accordingly, the particular arrangements disclosed are meant to be illustrative only and not limiting as to the scope of the invention, which is to be given the full breadth of the appended claims, and any and all equivalents thereof. 

1. A magnetic crash sensor, comprising: a. at least one coil in magnetic communication with at least a portion of a vehicle, wherein said at least said portion of said vehicle in magnetic communication with said at least one coil is susceptible to deformation responsive to a crash; b. a signal source operatively associated with said at least one coil, wherein said signal source provides for generating a first time-varying signal, and said first time-varying signal is operatively coupled to said at least one coil so as to cause said at least one coil to generate a magnetic field; and c. at least one circuit, wherein said at least one circuit comprises at least one sense resistor in series with said at least one coil, said current through said at least one coil and through said at least one sense resistor is responsive to said first time-varying signal, said first time-varying signal comprises a time-varying voltage, said current through said at least one coil and through said at least one sense resistor is also responsive to a magnetic condition of said at least one coil, and said magnetic condition is responsive to said magnetic communication of said at least one coil with said portion of said vehicle, and said at least one circuit generates a second signal responsive to a voltage across said at least one sense resistor.
 2. A magnetic crash sensor as recited in claim 1, wherein said at least one coil comprises a plurality of coil elements, wherein said plurality of coil elements are electrically interconnected in series with one another, and said plurality of coil elements are proximate to and are adapted to span a substantial region of a body or structural element of said vehicle, wherein said body or structural element of said vehicle is susceptible to deformation responsive to a crash.
 3. A magnetic crash sensor as recited in claim 2, wherein said plurality of coil elements are operatively coupled to a substrate.
 4. A magnetic crash sensor as recited in claim 1, further comprising a conductive element adapted to cooperate with said at least one coil so as to provide for shaping, controlling or limiting said magnetic field generated by said at least one coil.
 5. A magnetic crash sensor as recited in claim 1, wherein said at least one coil is adapted to magnetically cooperate with a gap between two portions of a body or structure of said vehicle.
 6. A magnetic crash sensor as recited in claim 5, wherein said gap is in series with a magnetic circuit of said vehicle.
 7. A magnetic crash sensor as recited in claim 5, wherein at least one axis of a corresponding said at least one coil is oriented substantially perpendicular to a surface bounding said gap.
 8. A magnetic crash sensor as recited in claim 5, wherein at least one axis of a corresponding said at least one coil is oriented substantially parallel to a surface bounding said gap.
 9. A magnetic crash sensor as recited in claim 5, wherein said at least one coil is bonded to a surface bounding said gap.
 10. A magnetic crash sensor as recited in claim 1, wherein said at least one coil comprises a ferromagnetic core.
 11. A magnetic crash sensor as recited in claim 1, wherein said at least one coil is operatively coupled to said body or structure of said vehicle with a fastener through a central portion of said at least one coil.
 12. A magnetic crash sensor as recited in claim 1, wherein said at least one coil is located between an outward facing surface of said body or structure of said vehicle and an inward facing surface of a proximate door of said vehicle.
 13. A magnetic crash sensor as recited in claim 1, wherein at least one said coil comprises a toroidal helical coil.
 14. A magnetic crash sensor as recited in claim 1, wherein said signal source comprises an oscillator.
 15. A magnetic crash sensor as recited in claim 14, wherein said first time-varying signal comprises a sinusoidal signal.
 16. A magnetic crash sensor as recited in claim 1, wherein said at least one circuit comprises at least one demodulator adapted to generate a third signal responsive to said second signal, and said third signal is responsive to a component of said second signal that is in-phase with said first time-varying signal.
 17. A magnetic crash sensor as recited in claim 16, further comprising a safety restraint system, wherein an actuation of said safety restraint system is controlled responsive to at least said third signal.
 18. A magnetic crash sensor as recited in claim 1, wherein said at least one circuit comprises at least one demodulator adapted to generate third and fourth signals responsive to said second signal, said third signal is responsive to a component of said second signal that is in-phase with said first time-varying signal, and said fourth signal is responsive to a component of said second signal that is in quadrature-phase with respect to said first time-varying signal.
 19. A magnetic crash sensor as recited in claim 18, wherein said third and fourth signals are responsive to, or provide a measure of, a self-impedance of said at least one coil.
 20. A magnetic crash sensor as recited in claim 18, further comprising a safety restraint system, wherein an actuation of said safety restraint system is controlled responsive to at least said third and fourth signals.
 21. A magnetic crash sensor as recited in claim 1, further comprising a safety restraint system, wherein an actuation of said safety restraint system is controlled responsive to said second signal.
 22. A magnetic crash sensor as recited in claim 1, wherein said at least one circuit comprises at least one element of the group consisting of a discrete electrical component, an analog circuit element, a logic circuit element, a logic array, and a computer processor. 